NEW SYLLABUS MATHEMATICS 3 (6th Edition) Specific

NEW SYLLABUS MATHEMATICS 3 (6th Edition) Specific Instructional Objectives (SIOs) ... OXFORD UNIVERSITY PRESS No. 38,...

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NEW SYLLABUS MATHEMATICS 3 (6th Edition) Specific Instructional Objectives (SIOs)

Authors: Teh Keng Seng BSc,Dip Ed Loh Cheng Yee BSc,Dip Ed

SET A This file contains a specified/suggested teaching schedule for the teachers.

OXFORD UNIVERSITY PRESS No. 38, Sector 15, Korangi Industrial Area P.O. Box 8214, Karachi 74900 Pakistan (021) 111 693 673 uan (021) 5071580-86 telephone (021) 5055071-2 fax [email protected] e-mail

© Oxford University Press All rights reserved. No part of this publication may be reproduced, translated, stored in a retrieval system, or transmitted, in any form or by any means, without the prior permission in writing of Oxford University Press, Pakistan.

NSM 3 [6th Edition]

Week

Topic

Specific Instructional Objectives

Exercises

Term 1 Chapter 1



Solve quadratic equations by factorisation (revision).

1a

Week 1, 2 &3



Form a quadratic equation when the roots are given

1a



Complete a given expression of the form ( x + kx) to obtain a perfect square.

1b



Solve a quadratic equation by ‘completing the square’ method.

1c

Solutions to Quadratic Equations



2

Maths Communication NE Pg 14 Discuss why we have COE & ERP and whether they are necessary and effective.

Maths Investigation

NE Pg 22 Discuss the need for taxes and how the taxes are used in Singapore.

Pg 33, 36, 4142, 44

Problem Solving Pg 5, 14

NE

IT

Resources

Pg 14 Example 14

Pg 3, 10 Refer to TG

Textbook

Pg 17 Exercise 1f Q16

Solve a quadratic equation by using the formula − b ± b 2 − 4ac . 2a Solve a non-quadratic equation by reducing it to a quadratic equation.

1d

Solve problems involving quadratic equations.

1f



Use the Multiplication Law of Indices to simplify terms that involve positive indices.

2a



Use the Division Law of Indices to simplify terms that involve positive indices.

2b



Use the Power Law of Indices to simplify terms that involve positive indices.

2c



Use the various Laws of Indices to simplify terms that involve positive indices.

2c



State the Laws of Indices involving zero and negative indices and use them to evaluate numerical expressions with zero and negative indices.

2d

x=

• . • Term 1 Chapter 2 Week 4&6

Indices and Standard Form

1e

2

Pg 32, 36, 39, 43

Pg 22 Introduction Pg 49 Exercise 2h Q27 Pg 52 Review Questions 2 Q6

Textbook

NSM 3 [6th Edition]

Week

Topic

Specific Instructional Objectives •

State the Law of Indices involving fractional indices and use it to evaluate and simplify expressions involving them.



Solve equations involving indices.



Use the standard form to express very large or very small numbers.



Use the calculator to evaluate numbers involving standard form and power of a number.



State the properties of inequalities: (1) if x > y and y > z , then x > z. (2) if x > y , then x + z > y + z and x − z > y − z ,

Exercises

Maths Communication

Maths Investigation

Problem Solving

Discuss and give examples on how inequalities are used in everyday life situations.

Pg 55, 63

Pg 57, 59, 60, 62

NE

IT

Resources

2e

2f

Term 1 Chapter 3 Week 7&8

Linear Inequalities

2g

2h

3a

x y (3) if x > y and z > 0, then xz > yz and > , z z x y (4) if x > y and z < 0, then xz < yz and < , z z

Pg 61 Example 6 Pg 63 Exercise 3c Q1 & Q2 Pg 70 Review Questions 3 Q10

and use them to solve simple inequalities. •

Distinguish the difference between < and ≤ and use a number to represent them.

3b



Solve problems involving inequalities.

3c



Solve linear inequalities involving one variable.

3d

3

Textbook

NSM 3 [6th Edition]

Week

Topic

Specific Instructional Objectives

Exercises

Term 1 Chapter 4



Locate the position of a coordinate point on a graph and find the length of a line segment.

4a

Week 9& 10



Find the gradient of a line joining two given points.

4b



Find the equation of a straight line given its gradient m and one point on the line.

4c



Find the equation of a straight line joining two given points.

4c



Solve related problems involving equations of straight lines.

4c

Term 2 Chapter 5



State the properties and characteristics of Row, Column, Square, Equal and Null Matrices.

5a

Week 1&2



State the order of a matrix.

5a



Add and subtract two matrices of the same order.

5b



Multiply a matrix by a real number.

5c



Multiply two matrices.

5d



Solve everyday life problems by using matrices.

5e



Solve problems involving profit and loss.

6a

Solve problems involving further examples of percentages.

6b

Solve problems involving simple interest.

6c

Coordinate Geometry

Matrices

Term 2 Chapter 6 Week 3&4

Application • of Mathematics in Practical • Situations

4

Maths Communication Ask pupils to cite examples of how the idea of coordinate geometry is used in everyday life situations.

Maths Investigation Pg 79, 85

Problem Solving

Discuss how the idea of matrices is being used in spreadsheets and how these programs are useful in our everyday lives.

Pg 109, 110

Pg 95

Discuss the power of compound interest. Ask pupils to calculate the amount that one has to pay if one

Pg 135, 137, 139-140, 149,

Pg 132, 151

NE

IT

Resources

GSP: Pg 83, 84 Refer to TG

Textbook

Textbook

Pg 134 Exercise 6b Q8 & Q9 Pg 147 on taxation

Textbook

NSM 3 [6th Edition]

Week

Topic

Specific Instructional Objectives

Exercises



Solve problems involving compound interest.



Solve problems involving hire purchase.



Convert one currency to another.



Calculate simple taxation problems.



Solve problems involving personal and household finances.



Interpret and use tables and charts in solving problems.



Use different problem solving strategies to solve everyday life problems.

6i



Interpret and use conversion graphs.

7a

Interpret and use travel graphs.

7b

Draw graphs to represent practical problems.

7c

Solve problems involving linear graphs such as travel graphs and graphs in practical situations.

7d 8a

6d

6e 6f

Term 2 Chapter 7 Week 5&6

Linear • Graphs and Their • Applications •

6g 6h

Term 2 Chapter 8



Identify congruent triangles.

Week 7&8



State and use the congruency tests: SSS, SAS, AAS and RHS to test if two triangles are congruent.



Apply the congruency tests to solve given triangles.

8c



Identify similar triangles.

8d



State the tests for similarity between two triangles.

Congruent and Similar Triangles

8a, 8b

5

Maths Communication owes money to the credit card company where interest is charged at 24% per annum and compounded monthly. Ask why many people are made bankrupt in the face of credit card debts.

Discuss how congruent and similar figures are found and used in everyday life situations.

Maths Investigation

Problem Solving

NE

IT

Resources

Pg 153 Exercise 6h Q12 & Q13

Pg 171

Pg 176, 183

Textbook

Pg 204-205, 209-210, 220221

Pg 206, 216, 217 219, 220, 227

Textbook

NSM 3 [6th Edition]

Week

Topic

Specific Instructional Objectives •

Term 3 Chapter 9 Week 1, 2 &3

Area and Volume of Similar Figures and Solids

Term 3 Chapter 10 Week 4, 5 &6

Use the rules for similarity between two triangles to solve problems involving similar triangles.

Exercises

Maths Investigation

Problem Solving

Pg 242, 250

Pg 245, 251

NE

IT

Resources

8e



State that the ratio of the areas of any two similar figures is equal to the square of the ratio of any two corresponding lengths of the figures.



Use the above rule to solve problems involving the area and lengths of two similar figures.



State that the ratio of the volumes of any two similar solids is equal to the cube of the ratio of any two corresponding lengths of the solids.



Use the above rule to solve problems involving the volumes, areas and lengths of two similar solids.

9b



Define the three basic trigonometrical ratios in terms of the lengths of the hypotenuse side, opposite side and adjacent side with respect to an acute angle of a rightangled triangle.

10a



Find the value of a trigonometrical ratio using a calculator.

10b



Find the length of a side of a right-angled triangle using trigonometrical ratios.

10c



Find the value of an angle of a right-angled triangle using trigonometrical ratios.

10d



Solve problems involving angles and lengths of a rightangled triangle.

10e



Solve practical everyday life problems using trigonometrical ratios.

10f

Trigonometrical Ratios

Maths Communication

Pg 241, 242, 244, 251

9a

Pg 261, 273, 278

Pg 262, 273 Pg 272

6

Textbook

GSP: Pg 265-266

Textbook

NSM 3 [6th Edition]

Week

Topic

Term 3 Chapter 11 Week 7, 8 &9

Further Trigonometry

Specific Instructional Objectives

Exercises



Solve more complicated problems with the use of trigonometry.

10g



Find the value of trigonometrical ratios of an obtuse angle.

11a



State the formula for finding the area of a triangle:

11b

Area of ∆ABC =

1 1 1 ab sin C = bc sin A = ac sin B 2 2 2

and use it to solve the angles or sides of a triangle. •

State the sine rule

a b c = = and use it to sin A sin B sin C

11c

solve a triangle given two sides and one non-included angle or one side and two angles. •

Identify whether the ambiguous case occurs for a particular triangle and solve a triangle involving the ambiguous case.

11c



State the cosine rule a 2 = b 2 + c 2 − 2bc cos A and use it to solve a triangle given two sides and an included angle or given three sides.

11d



Find the bearing of one point from another and use the sine and cosine rules to solve problems involving bearing.

11e



Solve simple problems involving 3-D figures in the form of a cube, cuboid, right pyramid, circular cone and cylinder.

11f



Find the angle of elevation and depression in simple 3D problems.

11g

7

Maths Communication

Maths Investigation

Problem Solving

Pg 304, 308309, 311

Pg 321, 322

NE

IT

GSP: Pg 306-307

Resources

Textbook

NSM 3 [6th Edition]

Week

Topic

Term 3 Chapter 12 Week 10 &



Mensuration - Arc Length, • Sector Area, Radian • Measure

Term 4



Week 1

Exercises

Find the area and circumference of a circle, a quadrant and a semi-circle.

12a

Find the arc length and area of a sector.

12b

Define a radian and to convert an angle in radian to degree and vice versa.

12c

Use the formula s = rθ and A =

1 2 r θ to solve 2

problems involving arcs and sectors with angles expressed in radians.

Term 4 Chapter 13 Week 2, 3 &4

Specific Instructional Objectives

State the symmetric properties of a circle, (i) a straight line drawn from the centre of a circle to bisect a chord is perpendicular to the chord, (ii) equal chords are equidistant from the centre of a circle or centres of equal circles.

13a



Calculate the perpendicular distance between the centre of a circle and a chord and solve related problems.

13a



State the angle properties of a circle, (i) an angle at the centre of a circle is twice any angle at the circumference subtended by the same arc, (ii) a triangle in a semicircle with the diameter as one of its sides, has a right angle at the circumference, (iii) angles in the same segment of a circle are equal, and use the above properties to solve related problems.



State that angles in opposite segments of a circle are supplementary and use the property to solve problems involving angles of a quadrilateral on a circle and related problems on the property.

Maths Investigation Pg 338, 340341

Problem Solving Pg 341, 343, 352

Pg 371, 377378, 382

Pg 373

NE

IT

Resources Textbook

12d



Geometrical Properties of Circles

Maths Communication

13b

13c

8

GSP: Pg 365-367

Textbook

NSM 3 [6th Edition]

Week

Topic

Specific Instructional Objectives

Exercises



Use all the above properties to prove mathematical statements involving angle properties of circles.

13d



State the property that a tangent to a circle is perpendicular to the radius drawn to the point of contact. State the properties regarding tangents drawn from an external point, (i) tangents drawn to a circle from an external point are equal in length, (ii) tangents subtend equal angles at the centre, (iii) the line joining the external point to the centre of the circle bisects the angle between the tangents, and use the above properties to solve problems involving tangents to a circle.

13e

9

Maths Communication

Maths Investigation

Problem Solving

NE

IT

Resources

NEW SYLLABUS MATHEMATICS 2 & 3 (6th Edition) Specific Instructional Objectives (SIOs) for Normal (Academic) Level

SET A This file contains a specified/suggested teaching schedule for the teachers.

OXFORD UNIVERSITY PRESS No. 38, Sector 15, Korangi Industrial Area P.O. Box 8214, Karachi 74900 Pakistan (021) 111 693 673 uan (021) 5071580-86 telephone (021) 5055071-2 fax [email protected] e-mail

© Oxford University Press All rights reserved. No part of this publication may be reproduced, translated, stored in a retrieval system, or transmitted, in any form or by any means, without the prior permission in writing of Oxford University Press, Pakistan.

Secondary 3N(A)

Week

Topic

Term Chapter 6 1 Of Book 2

Specific Instructional Objectives

Exercises

• Identify a right-angled triangle and its hypotenuse.

6a

• Define the Pythagoras’ theorem and its converse and use Week Pythagoras’ proper symbols to express the relationship. 1, 2 & Theorem 3 • Apply the Pythagoras’ theorem to find the unknown side of a right-angled triangle when the other two sides are given. • Solve word problems involving right-angled triangles using Pythagoras’ theorem.

6a

6b

6b

Maths Maths Problem Communication Investigation Solving Pg 178

NE

IT

Resources Textbook

Pg 181: Find out how mathematics and music are related, how computer music are made etc. Pg 185: Find out more about Pythagorean Triples.

Term Chapter 9 1 Of Book 2

• Identify important features of quadratic graphs y = ax2 when a takes on positive and negative values.

9a

Week Graphs of 4, 5 & Quadratic 6 Functions

• Construct a table of values for x and y for a quadratic function.

9a

• Plot a quadratic graph from a table of values with/without the aid of a curved rule.

9a

• Identify the equation of a line of symmetry of a quadratic graph.

9b

• Find the values of x and y from the quadratic graph by locating the point/s of intersection of a graph and a straight line.

9b

• Express word problems into quadratic equation and solve the problem using graphical method.

2

Pg 261-262, Pg 263, 264-265 264

Graph- Textbook matica: Pg 262

Secondary 3N(A)

Week

Specific Instructional Objectives

Topic

Term Chapter 6 1 Of Book 3



Solve problems involving profit and loss.

6a

Solve problems involving further examples of percentages.

6b

Solve problems involving simple interest.

6c

Solve problems involving compound interest.

6d

Solve problems involving hire purchase.

6e



Convert from one currency to another.

6f



Calculate simple taxation problems.

6g



Solve problems involving personal and household finances.



Interpret and use tables and charts in solving problems.



Use different problem solving strategies to solve everyday life problems.

6i



Solve quadratic equations by factorisation (revision).

1a

• Week Application 7, 8 & of • 9 Mathematics in Practical • Situations •

Term Chapter 1 1 Of Book 3

• Week Solutions to 10 Quadratic • and Equations Term 2

Exercises



6h

Form a quadratic equation when the roots are given. Complete a given expression of the form ( x + kx) to obtain a perfect square.

1b

Solve a quadratic equation by ‘completing the square’

1c

2

3

Maths Maths Problem NE Communication Investigation Solving Pg 135, 137, Pg 132, Pg 134 Discuss the 139-140, 149 151 Exercise 6b power of Q8 & Q9 compound interest. Ask Pg 147 on pupils to taxation calculate the amount that one Pg 153 has to pay if one Exercise 6h owes money to Q12 & Q13 the credit card company where interest is charge at 24% per annum compounded monthly and why many people are made bankrupt in the face of credit card debts. Compare this to the rate that the loan sharks charged. NE pg 14 Discuss why we have COE & ERP and whether they are necessary and effective.

Pg 5, 14 Pg 14 Example 14 Pg 17 Exercise 1f Q16

IT

Resources Textbook

Pg 3, 10 Textbook Refer to TG

Secondary 3N(A)

Week

Specific Instructional Objectives

Topic

Week 1&2



NE

IT

Resources

− b ± b 2 − 4ac . 2a 1e



Solve non-quadratic equations by reducing it to a quadratic equation.



Solve problems involving quadratic equations.



Use the Multiplication Law of Indices to simplify terms that involve positive indices.

2a

Use the Division Law of Indices to simplify terms that involve positive indices.

2b

Use the Power Law of Indices to simplify terms that involve positive indices.

2c



Use the Various Laws of Indices to simplify terms that involve positive indices.

2c



State the Laws of Indices involving zero and negative indices and use them to evaluate numerical expressions with zero and negative indices.

2d



State the Law of Indices involving fractional indices and use it to evaluate and simplify expressions involving them.

2e



Solve equations involving indices.

2f



Use the standard form to express very large or very small numbers.

2g

Week Indices And • 3 & 4 Standard Form •

Maths Maths Problem Communication Investigation Solving

1d

method. Solve a quadratic equation by using the formula

x=

Term Chapter 2 2 Of Book 3

Exercises

1f

4

NE Pg 22 Pg 33, 36, 41- Pg 32, Discuss the need 42, 44 36, 39, for taxes and 43 how the taxes are used in Singapore.

Pg 22 Introduction Pg 49 Exercise 2h Q27 Pg 52 Review Questions 2 Q6

Textbook

Secondary 3N(A)

Week

Specific Instructional Objectives

Topic

Exercises



Use the calculator to evaluate numbers involving standard form and powers of a number.

2h

Term Chapter 4 2 Of Book 3



Locate the position of a coordinate point on a graph and find the length of a line segment.

4a

Week Coordinate 5, 6 & Geometry 7



Find the gradient of a line joining two given points.

4b



Find the equation of a straight line given its gradient m and one point on the line.

4c



Find the equation of a straight line joining two given points.

4c



Solve related problems involving equations of straight lines.

4c



Interpret and use conversion graphs.

7a

Interpret and use travel graphs.

7b

Draw graphs to represent to represent practical problems

7c

Solve problems involving linear graphs such as travel graphs and graphs in practical situations.

7d

Term Chapter 7 3 Of Book 3

• Week Linear Graph 1, 2 & and their • 3 Applications •

Term Chapter 9 3 Of Book 3 Week Area and 4, 5 & Volume of 6 similar figures and solids



State that the ratio of the area of any two similar figures is equal to the square of the ratio of any two corresponding lengths of the figures.



Use the above rule to solve problems involving the area and lengths of two similar figures.

5

9a

Maths Maths Problem Communication Investigation Solving

Ask pupils to cite Pg 79, 85 examples of how the idea of coordinate geometry is used in everyday life situations.

NE

IT

Resources

GSP: Pg Textbook 83, 84 Refer to TG

Pg 171

Pg 176, 183

Textbook

Pg 242, 250

Pg 245, 251

Textbook

Pg 241, 242, 244, 251

Secondary 3N(A)

Week

Specific Instructional Objectives

Topic

Term Chapter 10 3 Of Book 3 Week Trigono7, 8, 9 metrical & 10 Ratios



State that the ratio of the volumes of any two similar solids is equal to the cube of the ratio of any two corresponding lengths of the solids.



Use the above rule to solve problems involving the volumes, areas and lengths of two similar solids.

9b



Define the three basic trigonometrical rations in terms of hypotenuse side, opposite side and adjacent side with respect to an acute angle of a right-angled triangle.

10a



Find the value of a trigonometrical ratio using a calculator.

10b



Find the length of a side of a right-angled triangle using trigonometrical ratios.

10c

Find the value of an angle of a right-angled triangle using trigonometrical ratios.

10d



Solve problems involving angles and lengths of a right-angled triangle.

10e



Solve practical everyday life problems using trigonometrical ratios.

10f



Solve more complicated problems with the use of trigonometry. State the symmetric properties of a circle, (i) a straight line drawn from the centre of a circle to bisect a chord is perpendicular to the chord, (ii) equal chords are equidistant from the centre of a circle or centres of equal circles.

Week Geometrical 1, 2, 3 Properties of

Maths Maths Problem Communication Investigation Solving

Pg 261, 273, Pg 262, 278 273

NE

IT

Resources

GSP: Pg Textbook 265-266

Pg 272



Term Chapter 13 4 Of Book 3

Exercises



10g 13a

6

Pg 371, 377- Pg 373 378, 382

GSP: Pg Textbook 365-367

Secondary 3N(A)

Week

Specific Instructional Objectives

Topic

& 4 Circles

Exercises



Calculate the perpendicular distance between the centre of a circle and a chord and solve related problems.



State the angle properties of a circle, (i) an angle at the centre of a circle is twice any angle at at circumference subtended by the same arc, (ii) every angle in a semicircle is a right angle, (iii) angles in the same segment of a circle are equal, and use the above properties to solve related problems.



13a

13b

State the properties of angles in opposite segments of a circle are supplementary and use the above property to solve problems involving angles of a quadrilateral on a circle and related problems on angle properties of circles.



Use all the above properties to prove mathematical statements involving angle properties of circles.



State the property that a tangent to a circle is perpendicular to the radius drawn to the point of contact.



State the properties regarding tangents drawn from an external point, (i) tangents drawn to a circle from an external point are equal in length, (ii) tangents subtend equal angles at the centre, (iii) the line joining the external point to the centre of the circle bisects the angle between the tangents, and use the above properties to solve problems involving tangents to a circle.

7

13c

13d

13e

Maths Maths Problem Communication Investigation Solving

NE

IT

Resources

Secondary 3N(A)

Week

Topic

For Chapter 11 • Sec Of Book 3 4N(A) • Further Trigonometry



Specific Instructional Objectives

Exercises

Find the value of trigonometrical ratios of an obtuse angle.

11a

Maths Maths Problem Communication Investigation Solving Pg 304, 308- Pg 321, 309, 311 322

NE

IT

Resources

GSP: Pg Textbook 306-307

State the formula for finding the area of a triangle

∆ABC =

1 1 1 ab sin C = bc sin A = ac sin B and use 2 2 2

11b

it to solve a triangle. State the sine rule

a b c = = and use it to sin A sin B sin C

11c

solve a triangle given two sides and non-included angle or one side and two angles. •

Identify whether the ambiguous case occurs for a particular triangle and solve a triangle involving ambiguous case.



State the cosine rule a = b + c − 2bc cos A and use it to solve a triangle given two sides and an included angle or given three sides.



Find the bearing of one point from another and use the sine and cosine rules to solve problems involving bearing.

11e



Solve simple problems involving 3-D figures in the form of a cube, cuboid, right pyramids, circular cones and cylinders.

11f



Find the angle of elevation and depression in simple 3D problems. Find the area and circumference of a circle, a quadrant and a semi-circle.

11g

Find the length and area of a sector.

12b

For Chapter 12 • Sec Of Book 3 4N(A Mensuration- • Arc Length,

2

2

11c

2

8

11d

12a

Pg 338, 340- Pg 341, 341 343, 352

Textbook

Secondary 3N(A)

Week

Topic

Specific Instructional Objectives

Exercises

Sector Area, • Radian Measure •

Define a radian and to convert an angle in radian to degree and vice versa.

12c

Use the formula s = rθ and

A=

1 2 r θ to solve problems 2

Maths Maths Problem Communication Investigation Solving

NE

IT

Resources

12d

involving arcs and sectors expressed in radians. For Chapter 3 • Sec Of Book 3 5N(A Linear Inequalities

3a

State the properties of inequalities: (1) if x > y and y > z , then x > z. (2) if x > y , then x + z > y + z and x − z > y − z ,

x y > , (3) if x > y and z > 0, then xz > yz and z z x y < , (4) if x > y and z < 0, then xz < yz and z z

Discuss and give Pg 55, 63, examples on how inequalities are used in everyday life situation.

Pg 57, 59, 60, 62

Pg 70 Review Questions 3 Q10



Distinguish the difference between < and ≤ and use a number to represent them.

3b



Solve problems involving Inequalities.

3c



Solve linear inequalities involving one variable.

3d



State the properties and characteristics of Row, Column, Square, Equal and Null Matrices.

5a



State the order of a matrix.

5a



Add and subtract two matrices of the same order.

5b



Multiply a matrix by a real number.

5c

9

Textbook

Pg 63 Exercise 3c Q1 & Q2

and use them to solve simple inequalities.

For Chapter 5 Sec Of Book 3 5N(A Matrices

Pg 61 Example 6

Discuss how the Pg 109, 110 idea of matrices is being use in spread sheets and how these programmes are so useful in our everyday lives.

Pg 95

Textbook

Secondary 3N(A)

Week

Specific Instructional Objectives

Topic

Exercises



Multiply two matrices.

5d



Solve everyday life problems by using matrices.

5e

Identify congruent triangles.

8a

State and use the congruency tests: SSS, SAS, AAS and RHS to test if two triangles are congruent.

8a

Apply the congruency tests to solve given triangles.

8b



Identify similar triangles.

8c



State the tests for similarity between two triangles.



Use the rules for similarity between two triangles to solve problems involving similar triangles.

For Chapter 8 • Sec Of Book 3 5N(A • Congruent and Similar Triangles •

8d 8e

10

Maths Maths Problem Communication Investigation Solving

Discuss how Pg 204-205, Pg 206, congruent and 209-210, 220- 216, 217 similar figures 221 219, 227 are found and use in everyday life situations.

NE

IT

Resources

Textbook

NEW SYLLABUS MATHEMATICS 3 & 4 (6th Edition) Specific Instructional Objectives (SIOs) for Normal (Academic) Level

SET A This file contains a specified/suggested teaching schedule for the teachers.

OXFORD UNIVERSITY PRESS No. 38, Sector 15, Korangi Industrial Area P.O. Box 8214, Karachi 74900 Pakistan (021) 111 693 673 uan (021) 5071580-86 telephone (021) 5055071-2 fax [email protected] e-mail

© Oxford University Press All rights reserved. No part of this publication may be reproduced, translated, stored in a retrieval system, or transmitted, in any form or by any means, without the prior permission in writing of Oxford University Press, Pakistan.

Secondary 4N(A)

Week

Specific Instructional Objectives

Topic

Term Part of 1 Chapter 4 Of Book 2

• Change the subject of a simple formula. • Changing the subject of a formula involving squares, square roots, cubes and cube roots etc.

Week Algebraic 1 & 2 Manipulation • Finding the unknown in a formula. and Formulae Term Chapter 1 • Construct a table of values of x and y for 1 Of Book 4 (i) a cubic function, y = ax3 + bx2 + cx +d, (ii) a reciprocal function, y =

Week Graphical 3, 4, 5 Solution of & 6 Equations

a x

and y =

a x2

Exercise Maths Maths Problem s Communication Investigation Solving Pg 138, 4i 139, 143 4j

NE

IT

Resources Textbook

4k

1a ,

x

(iii) an exponential function, y = a , and plot the graphs of these functions on a piece of graph paper. •

Find the value(s) of x for a given value of y and the value of y for a given value of x from the graphs above.



Sketch graphs of quadratic functions of the form

y = ax 2 , y = ±( x − a )( x − b) and

1a

1b

y = ± ( x − p) + q where a, b, p and q are constants. 2



Draw the graphs of a quadratic function and use it to solve related quadratic equations graphically.

1b



Draw the graphs of cubic, reciprocal and exponential functions and use them to solve related equations graphically.

1b

2

Where do you find uses of graphs in everyday life situations?

Pg 26, 31 Use Graphmatica Pg 17, 37 to see the shape of graphs and to solve equations graphically.

GraphTextbook matica : Pg 3, 6, 9, 10, 19, 22, 25, 28

Secondary 4N(A)

Week

Term Chapter 2 1 Of Book 4



• Week Further 7 & 8 Graphs and Graphs • Applied to Kinematics •

Term Chapter 11 1 Of Book 3

Week 1&2

Interpret a velocity-time graph and use it to find the distance moved by calculating the area under the curve; find the instantaneous acceleration at any point of time by finding the gradient of the tangent of the velocitytime graph at that time.



Draw a velocity-time graph from given information and use it to solve problems on distance, average speed and acceleration.

• •

Solve problems relating to graphs in practical situations. Find the value of trigonometrical ratios of an obtuse angle.

Week Further • 9 & 10 Trigonometry & Term 2

Exercise Maths Maths Problem NE IT Resources s Communication Investigation Solving Textbook GraphPg 43, 45 Pg 42, Pg 50 2a Convert speeds from km/h to m/s and vice versa. 58, 68, Exercise 2a matica : Just For Fun Q3 & Q5 Pg 47-48 70 Ask for various Find the gradients of a curve by drawing a tangent to the 2a answers and let curve. Pg 68 pupils explain how Review they got them. Draw the distance-time graph from given information Questions 2 2a and use it to find the velocity and solve related Q4 problems.

Specific Instructional Objectives

Topic



2b

2b

2b 11a

State the formula for finding the area of a triangle

∆ABC =

1 1 1 ab sin C = bc sin A = ac sin B 2 2 2

11b

and use it to solve a triangle. State the sine rule

a b c = = and use it sin A sin B sin C

11c

to solve a triangle given two sides and non-included angle or one side and two angles.

3

Pg 304, 308- Pg 321, 309, 311 322

GSP: Pg 306-307

Textbook

Secondary 4N(A)

Week

Specific Instructional Objectives

Topic

Term Chapter 12 2 Of Book 3

Exercise Maths Maths Problem s Communication Investigation Solving 11c



Identify whether the ambiguous case occurs for a particular triangle and solve a triangle involving ambiguous case.



State the cosine rule a = b + c − 2bc cos A and use it to solve a triangle given two sides and an included angle or given three sides.



Find the bearing of one point from another and use the sine and cosine rules to solve problems involving bearing.



Solve simple problems involving 3-D figures in the form of a cube, cuboid, right pyramids, circular cones and cylinders.



Find the angle of elevation and depression in simple 3D problems.

11g



Find the area and circumference of a circle, a quadrant and a semi-circle.

12a

Find the length and area of a sector.

12b

Define a radian and to convert an angle in radian to degree and vice versa.

12c

Week Mensuration- • 3 & 4 Arc Length, Sector Area, • Radian Measure •

2

2

Use the formula s = rθ and

NE

IT

Resources

2

A=

1 2 r θ to solve 2

11d

11e

11f

12d

problems involving arcs and sectors expressed in radians.

4

Pg 338, 340- Pg 341, 341 343, 352

Textbook

Secondary 4N(A)

Week

Topic

Term Chapter 5 2 Of Book 4

Specific Instructional Objectives • Construct a cumulative frequency table from a given frequency distribution table.

Week Cumulative • Draw a cumulative frequency curve and use it to estimate 5, 6 & Frequency the number or percentage of particular participants 7 Distribution exceeding or falling short of a figure. • Find the median, lower and upper quartiles and percentiles from a cumulative frequency curve and use them to find inter-quartile range and solve other related problems.

Term Chapter 6 3 Of Book 4 Week More on 1, 2 & Probability 3

Exercise Maths Maths Problem s Communication Investigation Solving Pg 174 Pg 189, 5a 206

IT

Resources

Excel: Pg Textbook 182-183

5a

5b

• Able to comment and compare the performance of two sets of data based on the median and inter-quartile range of the data.

5b

• Draw a box-and-whisker plots from a set of data.

5c

• Able to comment and compare the performance of two sets of data based on box-and-whisker plots of the sets of data.

5c

• Define the classical definition of probability of an event E occurring as P(E)=

NE

6a

No. of outcomes favouable to the occurence of E Total number of equally likely outcomes • List the elements in the sample space of an experiment.

6b

• Use the possibility diagrams to list the sample space of simple combined events.

6c

5

Pg 224, 231, Pg 221, Discuss “Is it 232, 234-235, worthwhile to gamble? What are the odds? Is it better to bet on 4digit ‘BIG’ or ‘SMALL’?” Refer to Pg 362 and TG.

Textbook

Secondary 4N(A)

Week

Topic

Specific Instructional Objectives • Use the tree diagrams to list the sample space of simple combined events.

Exercise Maths Maths Problem s Communication Investigation Solving 6d

• Perform calculation using the addition law to find the probability of mutually exclusive events.

6d

• Perform calculation using the multiplication law to find the probability of independent events.

6e

NE

IT

Resources

• State that for any event E, 0 ≤ P(E) ≤ 1. • P(E)=0 if and only if the event E cannot possibly occur. • P(E)=1 if and only if the event E will certainly occur. • State the rule P(E) = 1 – P(E’) where E and E’ are complementary events. • Use all the above theory to solve problems involving two or more events. Term Chapter 7 3 Of Book 4 Week Revision 4 to 10

7a Pg 349: Should we onwards be proud of ourselves for being great gamblers? Pg 353: Can you give concrete examples where statistics are being distorted?

6

Pg 306, 317 322, 326, 327

Textbook

Secondary 4N(A)

Week

Specific Instructional Objectives

Topic

For Chapter 3 • Differentiate between scalars and vectors and give two Sec Of Book 4 examples of each. 5N(A) Vectors in • Represent a vector using proper terminologies and Two notations. Dimensions • Define and identify equal vectors. • Define and identify negative of a vector and the zero vector.

Exercise Maths Maths Problem s Communication Investigation Solving Pg 75 Pg 103 Pg 79 3a

NE

IT

Resources Textbook

3a

3a

3a

• Express a vector in column vector form. • Find the magnitude and direction of a vector in column vector form.

3b

• Use triangle law of vector addition to find the sum of and difference between two vectors.

3d

• Multiply a column vector by a scalar.

3e

• Express a given vector in terms of two component vectors.

3e

3c

• Define position vector. • Find the resultant of two position vectors. For Chapter 4 Sec Of Book 4 5N(A) Standard Deviation and Mean



Find the mean of a given grouped data.

4a



Calculate the standard deviation of a set of data.

4b



Calculate the standard deviation of a set of grouped data.

4b

7

Discuss how some statistics may be manipulated or misrepresented. What are the properties of

Excel: Pg Textbook 144

Secondary 4N(A)

Week

Specific Instructional Objectives

Topic •

Able to comment and compare the performance of two sets of data based on the mean and standard deviation.

Exercise Maths Maths Problem s Communication Investigation Solving 4b standard deviation and how they are used in everyday situations.

8

NE

IT

Resources

NEW SYLLABUS MATHEMATICS 2, 3 & 4 (6th Edition) Specific Instructional Objectives (SIOs) for Normal (Academic) Level

SET A This file contains a specified/suggested teaching schedule for the teachers.

OXFORD UNIVERSITY PRESS No. 38, Sector 15, Korangi Industrial Area P.O. Box 8214, Karachi 74900 Pakistan (021) 111 693 673 uan (021) 5071580-86 telephone (021) 5055071-2 fax [email protected] e-mail

© Oxford University Press All rights reserved. No part of this publication may be reproduced, translated, stored in a retrieval system, or transmitted, in any form or by any means, without the prior permission in writing of Oxford University Press, Pakistan.

Secondary 5N(A)

Week

Specific Instructional Objectives

Topic

Term Chapter 8 1 Of Book 3



Identify congruent triangles.

8a

State and use the congruency tests: SSS, SAS, AAS and RHS to test if two triangles are congruent.

8a

Apply the congruency tests to solve given triangles.

8b



Identify similar triangles.

8c



State the tests for similarity between two triangles.

8d



Use the rules for similarity between two triangles to solve problems involving similar triangles.

8e



Define the term ‘set’.

10a

Write a statement using proper set notations and symbols.

10a

• Week Congruent 1, 2 & And Similar 3 Triangles •

Term Chapter 10 1 Of Book 2

Exercises

• Week Set Language 4, 5 & and Notation • 6 •

Use Venn diagrams to represent a set. Define and identify an empty set and universal set.

10b



Define and identify equal sets, disjoint set and complement of a set and to give examples of these sets.

10c



Define and distinguish subsets and proper subsets of a given set.



Define the intersection and union of sets and the relationships between sets by using Venn diagrams.

2

10d

Maths Maths Problem Communication Investigation Solving Pg 204-205, Pg 206, Discuss how congruent and 209-210, 220- 216, 217 219, 227 similar figures 221 are found and use in everyday life situations.

The origin and use of sets.

Pg 290

NE

Pg 296, Pg 290 302 Activity B

IT

Resources Textbook

Textbook

Secondary 5N(A)

Week

Specific Instructional Objectives

Topic

Term Chapter 3 1 Of Book 3

Exercises



Use Venn diagrams to solve problems involving classification and cataloguing.



State the properties of inequalities: (1) if x > y and y > z , then x > z. (2) if x > y , then x + z > y + z and x − z > y − z ,

Week Linear 7, 8 & Inequalities 9

3a

x y (3) if x > y and z > 0, then xz > yz and > , z z x y (4) if x > y and z < 0, then xz < yz and < , z z

Maths Maths Problem Communication Investigation Solving

Discuss and give Pg 55, 63, examples on how inequalities are used in everyday life situation.

Pg 57, 59, 60, 62

Distinguish the difference between < and ≤ and use a number to represent them.

3b



Solve problems involving Inequalities.

3c



Solve linear inequalities involving one variable.

3d

Term Chapter 5 1 Of Book 3



State the properties and characteristics of Row, Column, Square, Equal and Null Matrices.

5a

Week Matrices 10



State the order of a matrix.

5a



Add and subtract two matrices of the same order.

5b



Multiply a matrix by a real number.

5c



Multiply two matrices.

5d



Solve everyday life problems by using matrices.

5e

&

3

Resources

Textbook

Pg 70 Review Questions 3 Q10



Week 1&2

Pg 61 Example 6

IT

Pg 63 Exercise 3c Q1 & Q2

and use them to solve simple inequalities.

Term 2

NE

Discuss how the Pg 109, 110 idea of matrices is being use in spread sheets and how these programmes are so useful in our everyday lives.

Pg 95

Textbook

Secondary 5N(A)

Week

Specific Instructional Objectives

Topic

Term Chapter 4 2 Of Book 4 Week Standard 3, 4 & Deviation 5 and Mean

Term Chapter 3 3 Of Book 4



Find the mean of a given grouped data.



Calculate the standard deviation of a set of data.

Exercises 4a

4b •

Calculate the standard deviation of a set of grouped data.



Able to comment and compare the performance of two sets of data based on the mean and standard deviation.

• Differentiate between scalars and vectors and give two examples of each.

4b

3a

Week Vectors in • Represent a vector using proper terminologies and notations. 1, 2, 3 Two & 4 Dimensions • Define and identify equal vectors.

3a

3a • Define and identify negative of a vector and the zero vector. • Express a vector in column vector form.

3a

• Find the magnitude and direction of a vector in column vector form.

3b

• Use triangle law of vector addition to find the sum of and difference between two vectors.

3c

• Multiply a column vector by a scalar.

3d

• Express a given vector in terms of two component vectors.

3e

4

Maths Maths Problem Communication Investigation Solving Discuss how some statistics may be manipulated or misrepresented. What are the properties of standard deviation and how they are used in everyday situations. Pg 75

Pg 103

Pg 79

NE

IT

Resources

Excel: Pg Textbook 144

Textbook

Secondary 5N(A)

Week

Topic

Specific Instructional Objectives

Exercises

Maths Maths Problem Communication Investigation Solving

NE

IT

Resources

• Define position vector. • Find the resultant of two position vectors.

3e 7a Pg 349 : Should onwards we be proud of ourselves for being great gamblers?

Term Chapter 7 3 Of Book 4 Week Revision 4 to 10

Pg 353 : Can you give concrete examples where statistics are being distorted?

5

Pg 306, 317 322, 326, 327

Textbook

Chapter 1

Secondary 3 Mathematics Chapter 1 Solutions to Quadratic Equations ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 5) Take A and B across, time taken = 2 minutes Take A back, time taken = 1 minute Take C and D across, time taken = 10 minutes Take B back, time taken = 2 minutes Take A and B across, time taken = 2 minutes Total time taken = 2 + 1 + 10 + 2 + 2 = 17 minutes

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

)

Date: ____________ Time allowed:

min

Secondary 3 IT Worksheet Chapter 1 Solutions to Quadratic Equations Textbook Page 3 Thinking skills used: Inferring, Comparing and Contrasting. Step 1 Open Graphmatica from the icon on the screen OR from Start, then Program, then Graphmatica Step 2 Go to “View”, “Graph Paper” to select “Rectangular”, go to “View” again to select “Grid Range”. Select range from –5 to 5 for left and right and from 8 to -12 for top and bottom. You can change these later on your own to see the different effects. Step 3 • For the curve y = 2 x 2 − 7 x , type y=2x^2-7x and press Enter to see the graph. Write down the coordinates of the point where the graph cuts the x-axis. (___ , ___), (___ , ___) • What is the approximate value of y when x = 3.5? ___________ (You can do this by selecting “coord curso” from the tool bar and move the cursor to the point on the graph where x = 3.5). • Sketch the graph in the space below.

The solutions of the equation 2 x 2 − 7 x = 0 are x = ______ or _______.

Teachers’ Resource NSM 3

© Oxford University Press

Step 4 •



Type y=3x^2-5x-8 for the curve y = 3 x 2 − 5 x − 8 and press Enter to see the graph. Write down the coordinates of the point where the graph cuts the x-axis. (___ ,___), (___ , ___) Sketch the graph in the space below.

The solutions of the equation 3x 2 − 5 x − 8 = 0 are x = ______ or _______.

Step 5 • •

Type y=2x^2-5x-3 and press Enter to see the graph. Write down the coordinates of the point where the graph cuts the x-axis. (___ ,___), (___ , ___) Sketch the graph in the space below.

The solution of the equation 2 x 2 − 5 x − 3 = 0 are x = ______ or _______.

Teachers’ Resource NSM 3

© Oxford University Press

We can also solve the equation (2x - 1)(x - 2) = 5 by finding the points of intersection of the curve y = (2x - 1)(x - 2) and y = 5. The x-coordinates of the points of intersection of these two graphs will give the solutions of the equation. Step 6 • •



Type y=(2x-1)(x-2) and press Enter to see the graph. Type y=5 and press Enter to see the graph. Write down the coordinates of the points where the two graphs intersect. (___, ___), (___, ___) The solution of the equation (2x - 1)(x - 2) = 5 are x= ______ or _______.

You can change the colour of the grid line or the x and y-axes by selecting “View”, “colors” and selecting the desired colours for your graphs, gridlines and background etc. Conclusion: We can find the solution of the equation 3x2 – 5x – 8 = 0 by drawing the graph of y = 3x2 – 5x – 8 and finding the points of intersection of the graph and the line y = 0, i.e. the x-axis.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

)

Date: ____________ Time allowed:

min

Secondary 3 IT Worksheet Chapter 1 Solutions to Quadratic Equations Textbook Page 10 Thinking skills used: Inferring, Comparing and Contrasting.

Step 1 Open Graphmatica from the icon on the screen OR from Start, then Program, then Graphmatica Step 2 Go to “View”, “Graph Paper” to select “Rectangular”, go to “View” again to select “Grid Range”. Select range from –6 to 6 for left and right and from 20 to -20 for top and bottom. You can change these later on to see the different effects. Step 3 • • •



For the curve y = 3x 2 − 5 x − 7 , we have a = 3, b = −5, c = −7 . What is the value of (b 2 − 4ac) ? ____________ Type y=3x^2-5x-7 and press Enter to see the graph. How many points does the graph cut the x-axis?_____________ What is the approximate value of y when x=3.5? ___________ [You can do this by selecting “coord curso” from the tool bar and move the cursor to the point on the graph where x = 3.5. The bottom of the screen shows the co-ordinates where the cursor is placed. Clicking the mouse one more time will let go of this function.] Sketch the graph in the space below.

Teachers’ Resource NSM 3

© Oxford University Press

Step 4 • • • •

Step 5 • • • •

For the curve y = 9 x 2 − 12 x + 4 , we have a = 9, b = −12, c = 4 . What is the value of b 2 − 4ac ? _____________ Type y=9x^2-12x+4 and press Enter to see the graph. How many points does the graph cut the x-axis?_____________ What is the approximate value of y when x = 2? ________ (Refer to Step 3 above). Sketch the graph in the space below.

For the curve y = 2 x 2 − 8 x + 9 , we have a = 2, b = −8, c = 9 . What is the value of b 2 − 4ac ? __________________ Type y=2x^2-8x+9 and press Enter to see the graph. How many points does the graph cut the x-axis?_____________ What is the approximate value of y when x=0.5? ____________ Sketch the graph in the space below.

Teachers’ Resource NSM 3

© Oxford University Press

You can change the colour of the grid line or the x and y-axes by selecting “View”, “colors” and selecting the desired colours for your graphs, gridlines and background etc. Before you do the next few graphs, clear the screen by selecting “Clear” from the tool bar. Step 6 • • • •

Step 7 • • • •

For the curve y = −4 x 2 + 13x − 2 , we have a = −4, b = 13, c = −2 . What is the value of b 2 − 4ac ? _____________ Type y=-4x^2+13x-2 and press Enter to see the graph. How many points does the graph cut the x-axis?_____________ What is the approximate value of y when x = 2.5? ___________ Sketch the graph in the space below.

For the curve y = −4 x 2 − 20 x − 25 , we have a = −4, b = −20, c = −25 . What is the value of b 2 − 4ac ? ___________________ Type y=-4x^2-20x-25 and press Enter to see the graph. How many points does the graph cut the x-axis?_____________ What is the approximate value of y when x = -0.8? ____________ Sketch the graph in the space below

Teachers’ Resource NSM 3

© Oxford University Press

Step 8 • • • •

For the curve y = −6 x 2 + 11x − 8 , we have a = −6, b = 11, c = −8 . What is the value of b 2 − 4ac ? ____________ Type y=-6x^2+11x-8 and press Enter to see the graph. How many points does the graph cut the x-axis?_____________ What is the approximate value of y when x = 2.4? ____________ Sketch the graph in the space below.

You may explore more about the shapes of other quadratic graphs by keying in more of such equations on your own.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

)

Date: ____________ Time allowed:

min

Secondary 3 IT Worksheet Chapter 1 Solutions to Quadratic Equations Similarity Between y = 3x² + 5x – 1

y = -3x² + 2x + 3

Differences Between y = 3x² + 5x – 1

y = -3x² + 2x + 3

Conclusion: ________________________________________________________________ ___________________________________________________________________________ ___________________________________________________________________________

Similarity Between y = x² + 3x + 7

y = -x² + 7x – 13

Differences Between y = x² + 3x + 7

y = -x² + 7x – 13

Conclusion: ________________________________________________________________ ___________________________________________________________________________

___________________________________________________________________________

Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 1 Solutions to Quadratic Equations GENERAL NOTES Teachers should revise the method of solving quadratic equations by factorisation with the pupils. Although solving quadratic equations by ‘completing the square method’ will not be examined in the GCE ‘O’ level examinations, its procedure will greatly help pupils to understand the concept of the derivation of the formula. It will also help pupils doing Additional Mathematics understand the topic on quadratic functions better. To stress the importance of ‘completing the square’ method, the teacher may wish to set a question on it in the class test. To help pupils memorise the formula for solving quadratic equations, the teacher may wish to ask pupils to write down the formula for every question that they are doing for exercise 1d and 1e. The teacher may find it useful to use the CD-ROM on quadratic equations produced by CDIS. It will be a good and stimulating IT lesson, as the contents are relevant to our syllabus and it is tailored for local use. To promote creative thinking, the teacher may ask pupils to set word problems that will lead to quadratic equations, pair off pupils to solve these equations in class and get them to point out any flaws or errors in the questions set.

Common Errors It is very common for pupils to assign wrong values for a, b, and c in quadratic equations. Emphasise that the general form of a quadratic equation is ax2 + bx + c = 0. For instance, in the equation x2 – 3x – 5 = 0, a = 1 (not 0), b = – 3 (not 3) and c = –5 (not 5). For the equation 5x – 3x2 – 7 = 0, a = –3 (not 5), b = 5 (not 3 or –3) and c = –7. At the end of the chapter, the teacher could point out to the pupils that the easiest method to solve a quadratic equation is by factorisation if the equation can be factorised easily. Otherwise, the use of formula is the choice. ‘Completing the square’ method is only used when a question specifically asks for its use. After learning the formula, some pupils will just memorise its use and equations which can be solved by easier methods are not noticed. For example, Question 14 of Exercise 1d will lead 1 1 to 32x2 + 18 = 26 which can be solved easily when expressed as x2 = and x = ± . But 4 2 some pupils may use the formula to solve this with a = 32, b = 0 and c = −8.

Teachers’ Resource NSM 3

© Oxford University Press

NE MESSAGES No one owes Singapore a living. We must find our own way to survive. Page 14 Example 14

Singapore is the first country in the world to introduce the COE and ERP systems as tools to control the vehicle growth in the 1990s. It has been a love-hate system for motorists in Singapore. On the one hand, the motorists love the COE system as it has been effective in curbing the growth of vehicle population and thus keeping the road less congested. On the other hand, the motorists hate the system because the COE is more expensive than the price of the vehicle itself. Teachers can lead pupils to debate the pros and cons of the COE and ERP system. Can Singapore run as efficiently without the COE and ERP? Are the COE and ERP systems designed by the government to generate more revenue? Ask for any suggestions to improve the system of controlling vehicle growth and at the same time satisfying the desire of Singaporeans to own cars. Would building more roads be a way out? Page 17 Exercise 1f Q16

We must do our best to preserve the good relations we have with our neighbouring country. We must not speak ill of our neighbour but we must also defend any wrong and unfounded accusations hailed against us. We wish our neighbours well as we are interdependent. Many Singaporeans have relatives in Malaysia. Singapore depends on Malaysia for a great part of her water supply and many Singaporeans have heavy investments in Malaysia. The trade with Malaysia is important for both countries. Singapore leaders and the Sultan of Johor have a long tradition of inviting each other to attend Hari Raya feast in Johor and the Chinese New Year celebration in Singapore. You may want to discuss with your pupils the issue of the constant traffic jams at the Causeway, the relatively under-used Second Link and the proposed bridge to replace the Causeway.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: 35 min Marks: 8

Secondary 3 Multiple-Choice Questions Chapter 1 Solutions to Quadratic Equations 1. The roots of the equation x2 – 11x + 30 = 0 are (A) 5, –6 (B) 6, –5 (C) 5, 6

(D) –5, –6

2. What must be added to 3x2 – 6xa to make it a perfect square? (A) a2 (B) 3a2 (C) 6a2 (D) 12a2

(E) no real roots.

( )

(E) 6

( )

3. Solve the equation 5x2 – 2x + 1 = 0, giving your answer correct to 2 decimal places where possible. (A) 0.69 or –0.29 (B) 0.29 or –0.69 (C) 0.69 or 0.29 (D) –0.69 or –0.29 (E) no real roots ( ) 4. Solve the equation 3x2 – 3x – 5 = 0, giving your answer correct to 2 decimal places where possible. (A) 1.88 or 0.88 (B) –1.88 or 0.88 (C) –1.88 or –0.88 (D) 1.88 or –0.88 (E) no real roots ( ) 5. Solve the equation 7 – 5x – 6x2 = 0, giving your answer correct to 2 decimal places where possible. (A) 0.74 or 1.57 (B) 0.74 or –1.57 (C) –1.57 or –0.74 (D) 1.57 or –0.74 (E) no real roots ( ) 6. The roots of the equation 2 + 6x – x2 = 0 are (A) –3 + 11 (B) –3 ± 11 (D) ±3 – 11 (E) 3 ± 11

(C) ±3 + 11 ( )

7. Two pipes P and Q fill a pool at a constant rate of 60 litres per minute and 40 litres per minute respectively. The pool can be filled in 50 minutes, 75 minutes or 30 minutes, depending on whether pipe P alone, pipe Q alone or both pipes P and Q are used. If the 1 pool is filled using pipe P alone for 3 of the time and, both pipes for the rest of the time, how many minutes does it take to fill the pool? 1 (A) 30 min (B) 37 2 min (C) 35 min (D) 40 min (E) none of the above ( )

Teachers’ Resource NSM 3

© Oxford University Press

8. Thomas, John and Larry each drives 150 km of a 450 km journey from Singapore to Kuala Lumpur at speeds of 80, 100 and 120 km/h respectively. What fraction of the total time does Thomas drive? 4 15 15 (B) 15 (C) 37 (A) 74 3 5 (D) 5 (E) 4 ( )

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. 5.

C B

2. 6.

Teachers’ Resource NSM 3

B E

3. 7.

E E

4. 8.

D C

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: min Marks:

Secondary 3 Mathematics Test Chapter 1 Solutions to Quadratic Equations 1. Factorise completely. (a) ab – a – b + 1 (b) b (b + 1) − c (c + 1) (c) 54 – 6y2

[2] [2] [2]

2. Factorise each of the following completely. (a) x3y – 4xy3 (b) y2 – x2 + 6x – 9

[2] [2]

3. (a) Factorise completely 4a2 – b2. (b) Factorise 3x2 – 2x – 1.

[1] [2]

9v − 21

(c) Simplify 9v2 − 49

[2]

4. Solve the following equations (a) (x + 2) (x – 2) = 5 (b) (4x + 1)2 = 9 (c) 4x2 + 4x – 63 = 0

5. Solve the equations (a) 4x2 – 9x = 0

(b)

[2] [2] [2] 8x − 22 − x2 2x − 14

[4]

6. Solve the following equations where possible. (a) 3x2 + 4x = 8 (b) 8x – 3 = x2 (c) 2x2 – 3x + 5 = 0

[3] [3] [3]

7. Factorise each of the following completely. (a) (x – y + 3) (x – y) – 4 (b) 4x2 + 8x (c) 6x2 + 7x – 5 (d) 3a3 – 12ab2

[2] [1] [2] [2]

8. Factorise the following expressions completely. (a) 2x2 – 8x (b) 2x2 + xy – 3y2 (c) x2 – 2xy – 35y2

[1] [2] [2]

Teachers’ Resource NSM 3

© Oxford University Press

9. Solve the following equations, giving your answers correct to 2 decimal places where necessary. (a) x2 – 10x = 24 [2] (b) 3x2 – 2x = 7 [3] (c) (x + 2) (x + 3) = x + 11 [2] x2 − 5x + 6

10. (a) Simplify (x − 2) (3x + 4) (b) Solve the equations (i) x2 = 3x (ii) 3x2 + 13x = 10 (iii) x2 – x = 6

[2] [2] [2] [2]

11. Solve the following equations, giving your answers correct to 3 significant figures where necessary. (a) 12x2 – x = 20 [2] 2 (b) 2x – 7x = 7(5 – x) [2] (c) 5x2 – 4x = 3(x – 7x2) [2] 12. (a) Factorise 2x3 – 32x completely. [2] (b) Factorise x2 – 12x + 35. Hence or otherwise, solve the equation x4 – 12x2 + 35 = 0, giving your answers correct to 2 decimal places. [6] 13. Given that 4x2 + 12x + k is a perfect square, find the value of k.

[2]

14. (a) Given that x + 3y = 5 and x – 3y = 2, find the value of 2x2 – 18y2. (b) Factorise 4a2 – (3b – c)2 completely.

[2] [2]

15. In the diagram, ABCD is a rectangle in which AB = x cm and BC = 8 cm. ARSD and PQBR are squares, and the area of PQCS is 15 cm2. Find the length of PQ in terms of x, and form a quadratic equation in x. Solve this equation to find the possible values of the length AB. [6]

16. Given that x + y = 6 and x2 – y2 = 20, find the value of 4x – 4y.

[2]

17. Solve the equation t2 – 7t – 3 = 0, giving your answers correct to 2 decimal places.

[3]

18. Given that x + y = 8 and x2 – y2 = 20, find the value of 3x – 3y.

[3]

19. Solve the equation 2x2 + 9x – 17 = 0 by “completing the square” method, giving your answers correct to 2 decimal places. [4] 20. Solve the equation x2 – 7x – 13 = 0 by “completing the square” method, giving your answers correct to 2 decimal places. [4] Teachers’ Resource NSM 3

© Oxford University Press

21. Express y = 3x2 – 12x + 7 in the form y = a (x + b)2 + c. State the values of a, b and c. [4]

22. (a) Solve the equation 6x2 + x – 35 = 0 by factorisation. [2] (b) Solve the equation 3x2 – 6x – 13 = 0 by completing the square, giving your answers correct to 2 decimal places. [4] (c) Solve the equation 5x2 – 14x – 17 = 0 by using formula. Give your answers correct to 3 significant figures. [3]

23. Solve the following equations, giving your answers correct to 2 decimal places where necessary. (a) 2x (x – 3) = 3 (2x – 5) [3] 17

(b) 2x − 3 = 3x – 1

[3] 5

24. Solve the equation 3x + 9 = x , giving your answers correct to two decimal places.

[4]

25. Factorise 2x2 + 8x + 6. Hence, write down the prime factors of 286.

[3]

26. A car travels from Singapore to Kuala Lumpur, covering a distance of 390 km in a period of x hours. A slow train travels the same distance and it takes 4 hours more to reach the destination. Write down, in terms of x, (a) the average speed of the car in km/h, [1] (b) the average speed of the train in km/h. [1] (c) If the average speed of the train is 55 km/h faster than the train, form an equation in x and show that it reduces to 11x2 + 44x – 312 = 0. [4] Solve the above equation to find (d) the average speed of the car for the journey, [3] (e) the time taken by the slow train to travel from Singapore to Kuala Lumpur, giving your answer correct to the nearest minute. [2]

27. A motorboat can sail at a constant speed of x km/h in still water. When it sails with the 1

current in a river, its speed is increased by 3 2 km/h and when it sails against the current, its 1

speed is decreased by 3 2 km/h. The boat sails from village A to village B against the current and from village B to village C with the current on its way back. Given that the distance from village A to village B is 12 km, that from village B to village C is 9 km and that the total time taken for the whole journey of 21 km is 75 minutes, (a) write down expressions, in terms of x, for the time taken by the boat to travel from (i) village A to village B, [1] (ii) village B to village C, [1] [4] (b) form an equation in x and show that it reduces to 20x2 – 336x = 413, (c) solve the above equation giving your answer correct to 2 decimal places and state the time taken for the boat to travel from village B to village C, giving your answer correct to the nearest minute. [4]

Teachers’ Resource NSM 3

© Oxford University Press

28. An aircraft flew a distance of 3800 km from Singapore to Perth in Australia at an average speed of v km/h. (a) Write down an expression in terms of v for the time taken in hours for the journey. [1] The aircraft returned by the same route at an average speed of (v + 50) km/h. (b) Write down an expression in terms of v for the time taken in hours for the return journey. [1] (c) Given that the difference in time between the two journeys is 20 minutes, form an equation in v and show that it reduces to v2 + 50v = 570 000. [3] (d) Solve the above equation, giving your answer correct to 1 decimal place. Hence write down the time taken for the journey from Perth to Singapore, giving your answer correct to the nearest minute. [4] 29. A community club chartered a bus for $1200 to take a group of people for a sightseeing-cumshopping trip to Johor. It is agreed that each member of the group pay an equal share of the hire of the bus. The group initially consists of x people. (a) Write down an expression, in terms of x, for the amount of money each member of the group has to pay initially. [1] (b) On the day of departure, four members of the group could not make it for the trip. The club decided to contribute $30 from its fund and each of the remaining members had to pay an additional $5 in order to cover the cost of $1200. (i) Write down an expression, in terms of x, for what each member has to pay when the four members cannot make the trip. [1] [3] (ii) Form an equation in x and show that it reduces to x2 + 2x – 960 = 0. (iii) Solve the above equation to find the actual amount each member paid for the trip. [2]

30. Solve the following equations, giving your answer correct to three significant figures where necessary. (a) x2 – 10x + 9 = 0 (b) 6x2 + x – 12 = 0 (d) 3x2 – 22x – 16 = 0 (c) 2x2 – x – 10 = 0 3 (f) x + 1 = 4 (1 – x) (e) x2 + 7x – 5 = 0 (h) 3x2 – 11x – 17 = 0 (g) 2x2 – 13x + 7 = 0 2 (i) 4x = 12x + 1 (j) 5x2 – 7x = 78 (l) 6xy + 8x – 9y = 12 [36] (k) 5x2 – 2x = 5x + 9 31. A craftsman and his apprentice working together can complete a project in 4 days. If each works on the project individually, the apprentice would have taken 6 days more than the craftsman. How long would it take for the apprentice to do the job alone? [6] 32. A water tank can be filled by two pipes together in 6 minutes. If the tank is filled by the pipes individually, it would take the smaller pipe 5 minutes longer than the big pipe. Find the time in which each pipe alone would fill the tank. [6]

Teachers’ Resource NSM 3

© Oxford University Press

1 33. A man bought a toy car for $x and sold it for $78, thus making a profit of 2 x%. Find the value of x.

[4]

34. A rectangle has a diagonal 15 cm long. If the length of the rectangle is 3 cm longer than its width, find the length of the rectangle. [4] 35. The product of two consecutive even integers plus twice their sum is 164. Find the integers. [4] 36. The speed of a boat in still water is 12 km/h. The boat travels 18 km upstream and 40 km downstream in a total time of 4 hours 40 minutes. Calculate the speed of the current of the river. [4] 37. The area of a triangle is 15.4 cm2 and the height is 3.2 cm longer than the base. Find the length of the base. [4] 38. A piece of wire 48 cm long is bent to form the perimeter of a rectangle of area 72 cm2. Find the lengths of the sides of the rectangle. [4] 39. A rectangular photograph is placed on a sheet of vanguard paper measuring 25 cm by 18 cm. There is a border of uniform width x cm around the photograph. If the total [4] area of the border is 272 cm2, find the value of x. 40. A farmer uses 80 m of fencing to make three sides of a rectangular enclosure. The fourth side is a straight hedge. Find the length and width of the enclosure if the area enclosed is 600 m2.

[4]

41. If a train had travelled 8 km/h faster, it would have taken 45 minutes less to travel 350 km. Find the original speed of the train, giving your answer correct to the nearest km/h. [5] 42. The hypotenuse of a right-angled triangle is 22 cm and the sum of the other two sides is 30 cm. Find the lengths of the other two sides. [4] 43. A man made a car journey from Johor Bahru to Segamat, a distance of 195 km. For the first 150 km, his average speed was x km/h and for the last 45 km, his average speed was 10 km/h more than that for the earlier part. If the total time taken for the journey was 3 hours 15 minutes, form an equation in x and show that it reduces to 13x2 – 650x + 6000 = 0. Solve this equation and hence find the average speed for the last 45 km. [7]

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. (a) (a – 1) (b – 1)

(b) (b – c) (b + c + 1)

2. (a) xy (x + 2y)(x – 2y)

(b) (y + x – 3) (y – x + 3)

3. (a) (2a + b) (2a – b)

(b) (3x + 1) (x – 1)

(c) 3v + 7

4. (a) 3 or −3

(b) −1 or 0.5

(c) 3.5 or − 4.5

1

5. (a) 0 or 2 4

(b) 2 or 4

6. (a) 1.10 or −2.43

(b) 7.61 or 0.39

7. (a) (x – y – 1) (x – y + 4) (d) 3a (a + 2b) (a – 2b)

(c) 6 (3 + y) (3 – y)

3

(c) no real roots

(b) 4x (x + 2)

(c) (2x – 1) (3x + 5)

8. (a) 2x (x – 4)

(b) (2x + 3y) (x – y)

(c) (x – 7y) (x + 5y)

9. (a) 12 or −2

(b) 1.90 or −1.23

(c) 1 or −5

x−3

10. (a) 3x + 4 1

(b) (i) 0 or 3 1

2

(ii) 3 or −5

11. (a) 1 3 or −1 4

(b) ± 4.18

12. (a) 2x (x + 4) (x – 4)

(b) (x – 5) (x – 7) ; ± 2.24, ± 2.65

(iii) −2 or 3

(c) 0 or 0.269

13. k = 9 14. (a) 20

(b) (2a – 3b + c) (2a + 3b – c)

15. x – 8, x2 – 24x + 143 = 0, AB = 11 or 13 1

16. 13 3 17. 7.41 or − 0.41 1

18. 7 2 19. 1.43 or −5.93 20. 8.52 or −1.52

Teachers’ Resource NSM 3

© Oxford University Press

21. a = 3, b = −2, c = −5 1

1

22. (a) 2 3 or −2 2

(b) 3.31 or −1.31

23. (a) 4.22 or 1.78

(b) 1.5 or 3

(c) 3.72 or −0.915

1

24. 0.48 or −3.48 25. 2 (x + 1) (x + 3) ; 2, 11, 13 390

390

26. (a) x

27. (a) (i)

(b) x + 4 12 1 x−3 2

(ii)

9

(d) 105.7 km/h (c) x = 17.95, 25 min

1 x+3 2

28. (a)

3800 v

(b) v + 50

3800

29. (a)

1200 x

(b) (i) x − 4

(d) 730.4, 4h 52min

1200

(ii)

(e)

0.653, −7.65

(f)

(i)

3.08, − 0.0811

(j)

1 1 1 3 , −1 2 1 1 , − 2 2 4.71, − 3.31

12 days 10, 12 3.85 x = 49.3 or 0.72 ; 59.3 km/h

32. 36. 40.

10 min, 15 min 3 km/h 30, 10

30. (a) 1, 9

31. 35. 39. 43.

Teachers’ Resource NSM 3

(b)

(e) 7h 41min

1200 x

1170

+5= x−4

(iii) x = 30 ; $45

(c)

1 2 2 , −2

(d)

2 −3, 8

(g)

5.91, 0.593

(h)

4.84, − 1.17

(k)

2.21, −0.813

(l)

1 1 1 2 , −1 3

33. 60 37. 4.37 cm 41. 57 km/h

34. 12 cm 38. 3.51, 21.49 42. 19.1, 10.9

© Oxford University Press

Chapter 2

Secondary 3 Mathematics Chapter 2 Indices and Standard Form ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 32) -1 + 9 - 9 + 2 = 1 1×9–9+2=2 1+9–9+2=3 1+9÷9+2=4 1+ 9+ 9-2=5 1+9÷ 9+2=6

1 + 9 ÷ 9×2 = 7 19 – 9 – 2 = 8 1+ 9+ 9+2=9 (1 + 9 ) × 9 - 2 = 10 1 × 9 × 9 + 2 = 11 1 + 9 × 9 + 2 = 12

Thinking Time (pg 39)

The rule

a b

=

a b

is only applicable when a and b are positive integers.

Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 2 Indices and Standard Form GENERAL NOTES This will be the first time that pupils will be studying the topic on indices although they would have encountered indices with base 10 in Sec 2. Teachers can initiate discussion regarding the convenience of using indices and the application of this knowledge i.e. for very large or very small quantities. The mass of the Earth and that of an atom are two examples that students can comprehend easily. Other examples are the number of people on the planet Earth, the number of air molecules in a typical classroom, etc. Teachers may also wish to introduce some of the terms that are used to count extremely large and extremely small numbers such as those found in the British and American systems of numbers. One common difference is the value of ‘billion’ which is different in the British and American vocabulary although the American version is now commonly adopted. You may like to introduce this story of how a rich Chinese miser learned to count: The miser engaged a tutor to teach him how to write numerals. The tutor taught him how to write one, I, then the number two, II, which the miser learnt very quickly and then the number three, III. The miser found all these too simple and so found no necessity to learn further and pay more, so he dismissed the tutor thereafter. One day he wanted to write ten thousand and what a big and long piece of paper he needed! The index notation is a simple and short representation of the multiplication of the same number. Exploration on page 41 gives opportunities for students to practise looking for a pattern. Questions of this nature are common in mathematics competitions. Common Errors Made By Students Students have learnt the index notation in their primary school days and should hence find the first two laws easy to comprehend. However, many students tend to confuse the rules as they do the exercises. Some of the common errors involving indices are: 1. a 2 × a 3 = a 6 2. a 10 ÷ a 2 = a 5 3. a 3 + a 2 = a 5 4. a 8 − a 2 = a 6 6. (2 x 3 ) 3 = 2 x 9 5. (3 4 ) 2 = 9 8

1 2x3 9. 3 × 10 4 + 4 × 10 4 = 7 × 10 8

7. 2 x −3 =

Teachers’ Resource NSM 3

3 a −4 = 3 a4 10. (2a + b) 7 = 14a 7 + b 7

8.

© Oxford University Press

NE MESSAGES Page 22 Introduction

As only 689 500 people in Singapore pay income tax (in 2005), this turns up to be less than 20% of the population who are paying tax. Do you know how much tax do your parents pay? What are the other taxes that we have to pay to the government? Where do these tax monies go to? What are they used for? Part of these monies goes into paying the civil servants and government officers who work in government institutions. A portion of these monies also goes into defence, education and health care. Can you think of other areas where the tax monies could be utilised? How will the increase of GST from 5% to 7% (w.e.f July 2007) affect the people around you? Page 49 Exercise 2h Q27 Page 52 Review Questions 2 Q6

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: 35 min Marks:

Class: _______

14 Secondary 3 Multiple-Choice Questions Chapter 2 Indices and Standard Form

1. Simplify (2 xy 2 ) 3 ( x 2 y ) 4 . (A) 6 x 11 y 10 (B) 6 x 24 y 24 (D) 8 x 24 y 24 (E) 8 x 11 y 24 2. Simplify

( )

(2 x 2 ) 4 x2 ÷ . 3 xy 2 2y3

16 x 9 3y5 64 5 (E) x y 3

4 9 5 x y 3 32 5 (D) x y 5

(C)

(B)

(A)

3. Simplify (2 xy ) 3 ÷ 2 x 2 y . (A) 3xy 2 (B) 4xy 2

(C) 4 x 5 y

4. Solve the equation 32 x = 16. 1 4 1 (A) (B) (C) 1 2 5 4 5. Simplify

(C) 8 x 11 y 10

16 7 5 x y 3

( )

(D) 3x 5 y 2

(D)

1 4

(E) 8xy 2

( )

(E) Cannot be solved. ( )

( x −2 y 3 ) 2 . x 2 y −1

(A) x −2 y 7 (B) x −6 y 2

(C) x −6 y 6

(D) x −6 y 7

(E) x 6 y 4

( )

6. Simplify 210 × 310 . (A) 510 (B) 5 20

(C) 610

(D) 6 20

(E) 6100

( )

7. Simplify 4 x + 2 × 8 2− x . (A) 12 (B) 12 2

(C) 1210− x

(D) 4 3− x

(E) 2 x

( )

8. Simplify (A)

xy 2 3xz 3

10 xy 4 . 30 x 2 y 2 z 3 (B)

2 xy 2 3x 2 z 3

Teachers’ Resource NSM 3

(C)

y2 3xz 3

(D)

2y2 6 xy

(E)

y2 3xz 2

( )

© Oxford University Press

2

−1 − 9. Evaluate − ( 8 ) 3

.

1

(B) − 4

(A) 4

(C) 4 2

1

(D) − 4

−1

(E) 2

( )

1

10. Solve the equation 83 = (24x) 2 . 1

1

2

(B) 2

(A) 6

3x

3

(D) 1 2

(E) 1 4

( )

(C) 4x

(D) 42x

(E) 8x

( )

(C) x

(D) x0

(E) x−1

( )

1 x 2

11. Simplify 2 ÷ 4 × 64 (B) 2−x (A) 2x 2x

1

(C) 3

.

1

12. (x− 3 )−3 is equal to 1

(A) x−33

1

(B) x 9 1

2

13. Find the value of −(−27 )− 3 (A) 9

(B) −9

.

1

(C) 9

1

(D) − 9

1

(E) 3

( )

14. Solve the simultaneous equations 4x + y = 16; 3x – y = 81. (B) x = 4, y = −1 (C) x = 3, y = 1 (A) x = 4, y = 0 (E) x = 3, y = −1 (D) x = 3, y = 0

Teachers’ Resource NSM 3

( )

© Oxford University Press

Answers

1. C 6. C 11. B

2. D 7. C 12. C

Teachers’ Resource NSM 3

3. B 8. C 13. B

4. B 9. D 14. E

5. D 10. C

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: min Marks:

Secondary 3 Mathematics Test Chapter 2 Indices and Standard Form 2 1. Evaluate 2 3 + 3 2 − (1 ) −1 . 3 3

2

4

2

2. Simplify (-2x y ) ÷ 8x y

[2] −3

.

[2]

1 3 5 3. (a) Find the value of ( ) − 2 × ( ) 0 × ( ) 2 2 4 6 (b) Simplify the following and leave your answer in positive indices only: −3 2 −2 3 −2 (2x y ) (3x y ) 2

4. Evaluate each of the following: 0 −14 −1 + 2 (a) (8 ) 2 2 5 (b) ( ) −1 × ( ) − 2 ÷ 3 5 8

[2]

[1] [1] [1]

23 ( − x ) 3 ( 3x 3 ) 2 −2 3

[2]

[2]

5. Evaluate each of the following: 2 0 (a) 4 × 4 × 4 1 (b) ( ) − 2 4 2 3 (c) ( ) − 3 ÷ ( ) 0 3 4

6. Simplify (a)

[2]

[1] −2 3

(b) (2xy ) ÷ (4x y )

2

[2]

7. Simplify and express your answer in terms of positive indices only: (a) ( x −8 y 6 z 4 ) 2

3

(b) (a b )

−3



3 2

÷a

[2] −4 −7

b

Teachers’ Resource NSM 3

[2]

© Oxford University Press

8. Simplify the following, expressing your answer in positive index form: x 3 y −2 (a) x −1 y 3 (b)

[1]

(a −2b3 ) 4 ab − 4

[2]

9. Simplify the following: 4 −5 −2 (a) 2m × 3m ÷ m (b)

( 2ab) 2 21a 4 b 5

÷

[2]

8ab 4

[2]

7a 5 b 3

10. Given that a = 2 × 103 and b = 4 × 10-5, calculate the following and leave your answers in standard form. (a) ab

(b)

a b

(c) a +

1 b

[6]

11. (a) Express 0.005 724 in standard form. (b) Evaluate (8 × 103) × (3.2 × 10-2), giving your answers in standard form.

[4]

12. Evaluate the following and leave your answers in standard form. (a) 3.42 × 108 – 9.6 × 107 (b) (5.84 × 10-4) ÷ (2.0 × 10-15)

[4]

13. Evaluate the following, giving your answers in standard form. (a) 7 (1.23 × 10-4) (b) 0.46 × 105 + 75.8 × 104

[4]

14. Given that a = 6 × 108 and b = 4 × 106, find the value of each of the following in standard form. (a)

3a 2b

(b) a – 3b

15. Given that x = 2.8 × 10-5 and y = 7 × 103, find (a) 5xy2 (b) in standard form.

[4] 2y , leaving your answers x

[4]

16. (a) Rewrite 84.37 × 10-4 as a decimal. (b) Express 8.3674 × 104 in ordinary notation, correct to the nearest thousand. [3]

Teachers’ Resource NSM 3

© Oxford University Press

17. The population of Singapore is recorded as 3 947 000 in 2005. Express 0.000 045 23 cm in standard form correct to 2 significant figures. [2]

18. The radius of a micro-organism is 0.000 045 23 cm. Express 0.000 045 23 cm in standard form correct to 3 significant figures. [2] 19. Given that p = 9.5 × 107 and q = 5.0 × 10-6, calculate, expressing each answer in standard form, the value of (a) 2pq

(b)

p 4q

[4]

20. Evaluate each of the following: (a) (4.2 × 107) × (2.5 × 10-3) (c) (6.4 × 105) ÷ (20 × 10-3)

(b) (8.74 × 105) + (8.6 × 104) [4]

21. Given that x = 6 × 103 and y = 5 × 10-4, calculate the following and leave your answers in standard form. (a)

x y

(b) x +

2 y

22. If A = 3.4 × 107 and B = 0.374 × 109, find the value of

[4]

A , giving your answers in B−A

standard form.

[4]

23. A rectangular field measures 4.5 × 102 m by 3.6 × 102 m. Calculate its (a) area, (b) perimeter, giving your answers in standard form.

[4]

24. If the area of a circle is 2.54 × 106 cm, find the (a) radius, (b) perimeter of the circle, giving your answers in standard form correct to 3 significant figures. (Take π = 3.142) [4]

25. The population of Singapore was recently estimated to be three million, eight hundred and eighty thousand. (a) Write the number in standard form. (b) The total land area of Singapore is approximately 640 km2. Calculate the average number of people per square kilometer of the land area, giving your answer correct to 2 decimal places. [4]

Teachers’ Resource NSM 3

© Oxford University Press

26. Express the following in standard form: (a) 324 kg in g, (b) 1.2 km/min in cm/s. 4

27. Evaluate

28. Simplify

3 ×6

−5

4 × 10

×5

30. Simplify

−6

without using a calculator.

−5

( −2 x 3 y −4 ) 3 ( xy −1 ) −2 (4 x − 2 y − 3 ) 2

29. Simplify a n +1b 3 ÷

a n+4 a 2 b −5

.

1

3

1

2

7

15

[2] [2]

[1] [2]

7

[2]

7

33. Simplify the following: 4 7 −1 6 (a) (3a b )(5a b ) 72m −1 n 3 (b) 288m 3 n − 4

34. Simplify (

[2]

1

32. Evaluate each of the following, simplifying your answers as far as possible: 1 0 ) − ( 1997 ) 0 (a) (1997 ) 1 + ( 1997 3 84 27 3 (b) ( ) 0 + ( 4 ) − ( 3 ) 5 2 9

4 ×5 × 3

[3]

[2]

31. Evaluate (a) 7 2 × 7 4 ÷ 7 4 −2 −1 4 4 ×7 ×4 (b) 3 −3 7 ×4

(c)

[3]

.

( −2 x 3 y ) 2 giving your answer in positive indices. 6 xy 3

1

[4]

[1] [1]

x 2 y −3

x −3 y −1

x −5 y

x2 y3

)2 × ( 2

Teachers’ Resource NSM 3

) − 3 , giving your answer in positive indices.

[3]

© Oxford University Press

35. Solve the equation 5

2x − 3

1

=

25

.

[2]

36. Find the value of x when 6 x × 36 2 x − 5 = 1.

[2]

37. Solve the equation 9 2 x −5 =1.

[2]

38. Given that 3 x = 5 and 3 y =7, find the value of 3 4 x − 2 y .

[3]

39. Solve the equations: (a) 2 x × 4 x +2 × 8 x −1 = 64 (b) 5 x ÷ 25 x −1 = 125

[2] [2]

40. Solve the following equations: (a) 2 x × 4 x −1 = 16 1 (b) ( ) x ÷ 9 x = 81 x + 2 3

[2] [3]

41. Find the value of x given that 4 × 3 2 x −1 = 108.

[2]

42. (a) Simplify 7 2 x +1 – 4 (7 2 x ). (b) Use the result from (a) or otherwise, and solve the equation 7 2 x +1 – 4 (7 2 x ) = 1029.

[1] [2]

1 . 32

[3]

43. Solve the equation 2 x × 4 x + 1 ÷ 8 3 x − 4 =

44. Evaluate (0.1)−2 × 0.22 −

45. (a) Evaluate (0.027) (b) Simplify

1 − (16a4) 4

[2]

1 3

+ 160.75 + ⎛

1 2 −1



÷

1 (0.001a6)3

⎞ ⎠

0

+ (−3)−1.

.

[2] [2]

46. (a) Evaluate 1

(i) ⎛⎝ 81 ⎞⎠ 4 256

(b) Solve the equation 27x = 9

Teachers’ Resource NSM 3

2 −4

(ii) ⎛⎝3⎞⎠

[2] [1]

© Oxford University Press

47. Evaluate each of the following. (a) 65.5 ÷ 64.5 (b)

1 22

×

1 42

×

[1]

1 82

[2]

48. Evaluate −

(a) 23 + (32)

1 5

1

+ ⎛⎝3⎞⎠

2 0

2 1 3

(b) 43 × 4

[2]

49. Evaluate 2 (a) ⎛⎝3⎞⎠

5

−2

3

(b) 83

(c)

5 × 52

[3]

45x4y3 15x3y5 50. Simplify ÷ 23 . 4z5 8x z

[2]

51. Given that x2y = 3, find the value of 3x6y – 9.

[2]

52. Simplify each of the following. 1

3



(a) (a2 b2) 4 × (a2 b− 4) (b)

3

125x9 ÷

1 4

[2]

1 (81x− 4)2

53. (a) Given that 92x = −3

[2]

3 , find the value of x

[2]

⎛x ⎞ −2 with positive indices. 4 ⎟ ⎝y ⎠

(b) Express x2 ⎜

[2]

3 −3 −2

(c) Simplify

(a b ) ab

and express your answer with negative indices.

54. (a) Solve the equation 9x = 5 3 a 4 a4 (b) Simplify −3 a

Teachers’ Resource NSM 3

1 . 27

giving your answer with positive index.

[2]

[2]

[2]

© Oxford University Press

55. Evaluate (a) 32



4 5

[1] 1 ⎛9⎞ −12

(b) 2−3 × ⎝4⎠

×

⎛7 1⎞ 0 . ⎝ 2⎠

[2]

56. Evaluate each of the following. 1 0 (a) ⎛⎝7⎞⎠

(c) 64

1 3

[3]

1

1

57. Simplify



(b) (0.14)2 − 3a4 × 2a 2 −2

[2]

.

12a

3

2 −2

58. (a) Evaluate 164 + ⎛⎝3⎞⎠ . (b) Given that x−3 = 4, find the value of x3.

[2] [1]

59. (a) Simplify 4x5 × 5x4. (b) Find the smallest integer value of x for which 3x > 10. (c) Express

2x − 3 6



5x − 1 3

[1] [2]

1

+ 4 as a single fraction in its lowest terms.

[2]

60. Simplify the following and leave your answer in positive indices: (a)

1 −6 2 (x )

[1]

(b)

2 − −12 36 (x y ) 3

[2]

61. Simplify each of the following, giving your answer in positive indices only. (a) x 3 × x 2 ÷ x −4 (b) y 2 ÷ y 3 × y 7 (c) 2a 2 × 5a 3 (e) 6a 2 × (2a ) 3 ÷ 4a (g) 2( pq −2 ) 4 ÷ 4q −1

[8]

(d) 5a 3 × 2a −3 ÷ a 4 (f) (2 p −2 q 3 ) ÷ 4 pq (h) (a 2 ) −3 × a 4 ÷ a −1

62. Simplify each of the following, giving your answer in positive indices only. 8a 3 b 2 × 4a (3 xy ) 2 ÷ 4 x 2 y (a) (b) (2ab) 3 (2 xy ) 3 ÷ 8 xy 3

[4]

63. Simplify each of the following, giving your answer in negative indices only. [4] (a) x −4 × x −5 ÷ x −6 (b) a 7 ÷ a −2 × a −4 (c) (m 4 ÷ m −1 ) −2 (d) (2d −4 ) 3 ÷ 4d −1 Teachers’ Resource NSM 3

© Oxford University Press

64. Simplify each of the following, giving your answer in negative indices only. [6] (b) (ab −4 ) 5 ÷ a −1b −5 (a) (7 a 4 × 2a 3 ) 2 ÷ 14a 5 (c)

a 3 b × (2ab 4 ) 4 4a −1b − 4

(d)

3a (2b) 3 ÷ 8ab 2a 3 × (3b) 3

65. Simplify each of the following, giving your answer in negative indices only. [4] a 2 × (ab 3 ) 6 (−2 xy ) 2 ÷ 4 x 3 y 2 (a) (b) (2ab 4 ) −1 × 8a − 4 (4 x 2 y ) −2 × x 5 y 6 66. Express each of the following as a fraction or an integer. (a) 2 −3 × 5 2 (b) 230 ÷ 3 −3 × 2 4 1 3 (c) 4 −2 × 8 −1 ÷ 16 −2 (d) (1 ) − 2 × ( ) 2 ÷ (−2) − 2 2 4

[6]

67. Express each of the following as a fraction or an integer. [12] 1 (b) 4 −3 ÷ (5) − 2 ÷ (7 ) 0 (c) (3 −2 ) 2 ÷ (4 −1 ) 2 (a) 10 −1 × 5 2 ÷ 6 −2 2 1 (e) (2 −3 ) 4 ÷ (8 −1 ) 2 (f) 7 2 × 49 −3 ÷ ( ) − 4 (d) (−2) 3 ÷ (−3) −2 7 68. Solve the following equations:

[4]

1 64 7 (d) x = −1

(a) 3 x = 243

(b) 2 x =

(c) 23 x = 1 69. Solve the following equations: (a) 5 x 4 = 405

(b) 27 x 3 = 1

70. Solve the following equations: (b) 2 3 × 8 x = 0.25 (a) x −2 = 36

[6] (c) 5 x =

1 125 [6]

(c) 210 ÷ 4 = 2 x

71. Simplify the following, giving your answer with positive indices. (xy3)−1 a2 −1 (a) ( −2 ) (b) b (x−1y2) −3

[4]

72. Simplify the following, giving your answer with negative indices. p5q6 p− 4q−5 abc−1 a2b (b) −2 2 × −1 −3 −2 (a) −3 −1 × p2q3 q p (a b) (a c )

[6]

Teachers’ Resource NSM 3

© Oxford University Press

73. Simplify the following expressions. (a)

1 (2x2



3 (6x2

(c) (2a−1)4 ÷

)

1 − (8a 2

[4] −4

(b) 5x 4 )3

1 2

−1

÷ 4x

1 4 2

(d) 3a−2 ÷ (27a) 3

74. Evaluate the following: (a)

3 1692

[3] −

(b) 100

1 2

(c) (−8)

2 3

75. Evaluate the following:

[6] 1 −1 (b) (64 ) 3 + (−3)−2

1 3 1 (a) (38 )3 ÷ ( 8 )−1

1 1 −1 (c) (1 − 2 )−1 ÷ (24 ) 2

76. Solve the following equations.

[5] −

(a) x7 = 70

(b) 5

2 3

÷ 5 = 5x

(c) 4x = 0.125

77. Solve the following equations. (a) 82x + 1 = 32 (b) 105x − 1 = 0.001

x−1

(c) 3

[6]

×9

78. Solve the following equations.

= 27

2x − 4

[6] 1 x+3 2

(a) 42x − 1 = 8x + 3

x+3

(b) 16

= 8x + 1

79. Given that a = 4.2 × 105 and b = 8.3 × 104, find the value of the following, expressing your answer in standard form. [4] a (b) a – b (c) ab (d) b (a) a + b 80. Given that x-3 = 4, find the value of x3.

[2]

1

81. If p-2 = 5 q 3 , calculate the value of

[4] 2

(a) p when q = 125,

(b) q when p = 5 .

82. Given that x = 1.2 × 106, evaluate x + 10 4 . 1

[2] 2

3

83. Given that (ab)-2 = x 2 , find the value of x when a = 5 and b = 34 .

Teachers’ Resource NSM 3

[3]

© Oxford University Press

84. Evaluate each of the following without the use of a calculator, giving your answer in standard form correct to 4 significant figures. [10] 4 2 4 3 (a) 3.12 × 10 + 2.6 × 10 (b) 4.76× 10 − 6.13 × 10 (d) 3.24 × 108 − 9.86 × 107 (c) 7.91 × 109 + 6.14 × 108 -5 -6 (f) 8.59 × 1010 + 16.7 × 109 (e) 1.02 × 10 + 3.19 × 10 (g) 5.48 × 10-8 – 76.4 × 10-6 (h) 324 × 106 − 1.86 × 107 (j) 36.8 × 1018 − 485 × 1015 (i) 76.34 × 105 + 183.4 × 104 85. Use your calculator to evaluate each of the following, giving your answer in standard form correct to 4 significant figures. [10] (a) 3.18 × 104 × 6.45 × 102 (b) 4.59× 10-3 × 8.674 × 107 (d) 3.58 × 10-10 ÷ (7.61 × 10-9) (c) 5.43 × 109 ÷ (3.27 × 108) -5 -6 (e) 4.95 × 10 ÷ (3.14 × 10 ) (f) 6.45 × 102 ÷ (3.27 × 107) (h) 5.149 × 107 × 3.26 × 10-4 (g) 32.65 × 10-8 × 4.59 × 107 5 4 (j) 19.79 × 108 ÷ (39.76 × 10-3) (i) 34.95 × 10 × 672.6 × 10

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. 16

2. 2x 10 y 11

2 5

(b) −8 6. (a) 3 9x x 2 y12

(b)

11. (a) 5.724 × 10-3 (b) 2.56 × 102 16. (a) 0.000 843 (b) 84 000

12. (a) 2.46 × 108 (b) 2.92 × 1011 17. 3.9 × 106

21. (a) 1.2 × 107 (b) 1.0 × 104 26. (a) 3.24 × 105 (b) 2.0 × 103

22. 1.0 × 10-1

31. (a) 7

27.

1 60

36. 2

37. 2

41. x = 2 1

46. (a) (i) 1 3 1

4. (a) 1

(b)

b12 a9

10. (a) 8 × 103 (b) 5 × 107 (c) 2.7 × 104

a2 6b4

15. (a) 6.86 × 103 (b) 5 × 108 20. (a) 1.05 × 105 (b) 9.6 × 105 (c) 3.2 × 107 5 2 2 2 23. (a) 1.62 × 10 m 24. (a) 8.99 × 10 cm 25. (a) 3.88 × 106 (b) 1.62 × 103 m (b) 5.65 × 103 cm (b) 6.06 × 103 − x11 2 y4

14. (a) 2.25 × 102 (b) 5.88 × 108 19. (a) 9.5 × 102 (b) 4.75 × 1012

29.

1

30.

ab 2

34. x 29 y 2

35.

n7 4m

42. (a) 3(7 2 x ) (b) x = 1.5

43. 3

47. (a) 6 (b) 8

48. (a) 9 2

2 x5 3y 1 2

4

37 38. 12 49

39. (a) 1

1 6

(b) –1

1 6

40. (a) 2 (b) − 1

(b)

1

5 a3

6x3 50. z2y2

1

49. (a) 24 (b) 32 (c) 25

(b) 16

1 7

45. (a) 12

44. 4 1

(ii) 5 16

3 4

(c) 6

9. (a) 6m

x4 y5

(b)

2

5. (a) 64 (b) 16

(b) 15

33. (a) 15a 3 b 13

1

1 2

8

13. (a) 8.61 × 10-4 (b) 8.04 × 105 18. 4.52 × 10-5

28.

32. (a) 1997 (b) 230 (c) 16

1 (b) 12 4

4y

8. (a)

y9z6 1 (b) 2 2 a b

7

(b)

x 12

7. (a)

7 9 12 9x

3. (a) 2

(b) 3

51. 72

52. (a) a



5

1 8

(b) 9 x5

56. (a) 1 (b) 0.0196 1 (c) 4

57.

1 2

3 1 4

a

Teachers’ Resource NSM 3

b

2

1 2

1 53. (a) 8 8 (b) (xy) a−7 (c) −5 b 1

58. (a) 10 4 1

(b) 4

3

54. (a) − 4 5

(b) a

7 12

y−a 1 + k2 59. (a) 20x9

1

55. (a) 16 1

(b) 27

(c) x =

(b) x = 3

60. (a)

1

x3 x8 (b) 24 y

© Oxford University Press

61. (a) x 9

(b) y 6

p4 2q 7 4a 62. (a) b

1 a 9y (b) 4x 2 1 (b) −5 a b −15 (b) −6 a

(g)

63. (a) x −3

(d)

(e) 12a 4

(c) m −10

(d) 2d −11

(f)

2q 8 p7

(h)

14 a −9 1 65. (a) −13 − 22 a b 1 (b) 432 66. (a) 3 8 25 67. (a) 90 (b) 64

64. (a)

10 a4

(c) 10a 5

(c)

4 −8 − 21 a b

(d)

a −3 b −1 18

(b) 16 x −2 y −5 (c) 2

(d) 1 (c)

68. (a) 5

(b) -6

(c) 0

69. (a) ± 3

1 (b) 3

(c) -3

16 81

(d) -72

(e)

1 64

(f) 1

(d) -1

1 2 (b) − 1 (c) 8 6 3 y3 1 (b) 4 71. (a) 2 2 x a b

70 (a) ±

72. (a)

1 q−1

(b)

c−7 a−5

1 5 1 (b) 4 x−34 (c) a−33 1 (c) 4 74. (a) 2197 (b) 10 3 1 75. (a) 16 (b) 49 (c) 3 1 1 (c) −12 76. (a) 1 (b) −1 6 2 2 1 (c) 5 3 77. (a) − 12 (b) − 5 78. (a) 11 (b) 9 5 79. (a) 5.03 × 10 (b) 3.37 × 105

73. (a) 12x2

1 1 (d) 3 a−13

(c) 3.486 × 1010

(d) 1.976× 10-1

1 80. 4 1 81. 5 Teachers’ Resource NSM 3

© Oxford University Press

82. 1.1 × 103 16 83. 81 84. (a) 3.146 × 104 (e) 1.339 × 10-5 (i) 9.468 × 106

(b) 4.147 × 104 (f) 1.026 × 1011 (j) 3.632 × 1019

(c) 8.524 × 109 (g) -7.635 × 10-5

(d) 2.254 × 108 (h) 3.054 × 108

85. (a) 2.051 × 108 (e) 1.576 × 109 (i) 2.351× 107

(b) 3.981 × 105 (f) 1.972 × 10-5 (j) 4.977 × 1010

(c) 1.661 × 102 (g) 1.449 × 1013

(d) 4.704 × 10-2 (h) 1.679 × 104

Teachers’ Resource NSM 3

© Oxford University Press

Chapter 3

Secondary 3 Mathematics Chapter 3 Linear Inequalities ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 55) 1. +

2.

68411 2904 71315

A = 1, B = 4, C = 2, D = 8, E = 5, F = 7

Just For Fun (pg 57)

( 10 +

29

)

2

= 10 + 29 + 2 10 29 = 39 + 2 290 but17 = 289 and 73 = 39 + 2 × 17 2

∴ 39 + 2 290 > 39 + 2 × 17. Thus ( 10 + 29 ) 2 > 73 and 10 + 29 > 73 Just For Fun (pg 59) Take a cap from the one labelled “black and white”. If the cap taken is say, black, then we know that both caps in the bag must be black. Now that we have identified one bag, we can tell the contents of the bag labelled “white” to be the bag with one black and one white cap and the last bag containing white caps only. Just For Fun (pg 60) The 8 buns can be divided into 24 parts. The first traveller originally has 15 parts and the second traveller has 9 parts. The two travellers each ate 8 parts and the Arab ate the other 8 parts, thus the first traveller had given the Arab 7 parts and the second traveller had only given 1 part. Thus the first traveller must be entitled to 7 gold coins and the second traveller to get 1 gold coin. Just For Fun (pg 62) 1+5+5+7=2+4+4+8 12 + 52 + 72 = 22 + 42 + 42 + 82 7 + 11 + 11 + 13 = 8 + 10 + 10 + 14 1 + 5 + 5 + 7 + 8 + 10 + 10 + 14 = 2 + 4 + 4 + 8 + 7 + 11 + 11 + 13 12 + 52 + 52 + 72 + 82 + 102 + 102 + 142 = 22 + 42 + 42 + 82 + 72 + 112 + 112 + 132 13 + 53 + 53 + 73 + 83 + 103 + 103 + 143 = 23 + 43 + 43 + 83 + 73 + 113 + 113 + 133 is correct.

Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 3 Linear Inequalities GENERAL NOTES This chapter is moved from Secondary 2 to Secondary 3. It will be new to the Secondary 3 pupils. It provides a refreshing change from solving equations. The teacher may like to discuss the various examples of inequality in real life situations. There is inequality in every society, every family and every organization. Some people are born with a silver spoon in the mouth while others are not so fortunate. Some are born physically stronger than others and others are more intellectually inclined than their friends, etc. It could develop into a lively scene if teachers encourage students to name and discuss the many inequalities and social injustices in life. After introducing the inequality signs, teachers may like to ask the pupils to find out from the library or the internet as an extra exercise, the person in history who first introduces these signs. One way of introducing inequalities is by using concrete examples to lead pupils to arrive at the desired result. We know that 5 > 3. Is 5 + 2 > 3 + 2? Pupils normally will be quick to respond with an affirmative answer to which the teacher can proceed. From the above, we see that the inequality is still true when we add a positive number to both sides of an inequality. If x > y, then x + a > y + a where a is a positive number. (Use the same technique to introduce subtraction, multiplication and division of positive numbers to an inequality.) We know that 5 > 3. Is 5 – 2 > 3 – 2? Thus if x > y, then x – a > y – a where a is a positive number. We know that 7 > 4. Is 7 ×3 > 4 ×3? Thus if x > y, then xa > ya where a is a positive number. We have 8 > 4. Is Thus, if x > y, then

8 2

>

4 2

?

x y > where a is a positive number. a a

After introducing the above, the pupils may be asked to have some practice on the use of the above where only multiplication and division of positive numbers are involved. The teacher may now introduce the concept that when we multiply or divide both sides of an inequality by a negative number, we must change the inequality sign. We have 8 > 4. Is 8 ×(–2) > 4 ×(–2)? Is

Teachers’ Resource NSM 3

8 −2

>

4 −2

?

© Oxford University Press

x y < where a is negative. a a The pupils should be asked to work some sums based on the above rules before the short–cut method is introduced, i.e. the inequality sign may be treated as an equal sign where a single term may be transferred from the L.H.S. to the R.H.S. by changing the sign of the term.

Thus, if x > y, then x(a) < y(a) and

Common Errors Made By Students The most common error made by students is when an inequality is multiplied or divided by a negative number, they tend to forget to change the inequality sign. One way of overcoming the above is to ask the pupils to transfer the unknown terms to one side, so that later on only multiplication and division by positive numbers are involved. For example, 3x – 5 > 6x + 4 3x – 6x > 4 + 5 –3x > 9 x < –3

may be done as follows: 3x – 5 > 6x + 4 –5 – 4 > 6x – 3x –9 > 3x i.e. x < –3

NE MESSAGES

We must uphold meritocracy and incorruptibility. Page 61 Example 6, Page 63 Exercise 3c Q1, Page 70 Review Questions 3 Q10 Singapore practises meritocracy. All pupils who do well in their examinations, are rewarded irrespective of their race and religion. The government sets up the Edusave Endowment Fund in 1993 to fund children’s education and encourage them to do well in school. For secondary pupils, the top 5% of the pupils in each stream (Special, Express, Normal Academic and Normal Technical) in every school will receive $500 and the next 5% will receive $300 irrespective of their family’s income. The next 15% of the pupils in each stream in each school will be given a chance to apply for the Edusave Merit Bursary which will be administered by the Community Development Council and Citizens Consultative Committee. Only pupils from families whose total family income is less than $3000 per month are eligible to apply. Each successful applicant will receive $250. The Good Progress Award is given to pupils who have shown great improvement in their grades in the current year. Each secondary school pupil is rewarded with $150. Thus many pupils are encouraged to do well in their respective streams. This system awards the brightest and also encourages the less academically inclined pupils to work hard.

Teachers’ Resource NSM 3

© Oxford University Press

We must preserve racial and religious harmony. Page 63 Exercise 3c Q2 Singapore is a multi-racial and multi-religious society consisting of many races and religions. We must work hard to preserve racial and religious harmony. The Chinese Buddhist Lodge has done a good deed in extending a helping hand to the Malay Muslim community. This manifestation of compassion for people from other races and faith goes a long way to foster the cohesiveness of the Singapore society. Through many races, religions, languages and culture, we pursue our destiny. Teachers can elaborate on the many racial and religious conflicts that are happening in many parts of the world. We must not take racial and religious harmony for granted but make an effort to foster better understanding of each other’s religion and culture.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: 35 min Marks:

Class: _______

16 Secondary 3 Multiple-Choice Questions Chapter 3 Linear Inequalities 1. Solve the inequality: 2x + 3 > 5x – 7. 1

(A) x < 3

(B) x < 3

(D) x > 3

(E) None of the above.

2. If

1 5

<

1 x

(C) x > 3

3

1 3

( )

and x < 0, then

(A) 0 < x <

1

(B) –5 < x < 0

5

(C) 0 < x < 5

1

(E) − < x < 0

(D) x < –5

( )

5

3. Simplify the inequality 2y – 5 > 2x + 4y + 3. (A) y – x > 4 (B) y – x < x (D) y + x + 4 < 0 (E) y + x < 1

(C) y + x + 4 > 0 ( )

4. Solve the inequality 2x – 3 > 3x – 10. (A) x > 7

(B) x < 7

(C) x > –7

(D) x < –7

5. If 3x – 4 > 5x – 17, one possible value of which is prime is (A) 3 (B) 7 (C) 11 (D) 13

(E) x <

13 5

( )

(E) 17

( )

6. The largest integral value of x satisfying the inequality 3x + 7 ≥ 7x – 54 is (A) 6

(B) 14

(C) 15

1 4

(D) 15

(E) 16

( )

7. The smallest integral value of x satisfying the inequality 5x – 7 ≥ 2x – 21 is (A) −4

2 3

(B) 4

(C) 5

8. Which of the following is/are true? (I) –3 > –2 (II) –2 > –3 (A) I only (B) II only (D) II and III only (E) I and III only

Teachers’ Resource NSM 3

(D) –4

(E) –5

( )

(III) 0 < –2 (C) III only ( )

© Oxford University Press

9. If x + 6 > 3 and 2x – 3 < 7, then (A) 3 < x < 5 (B) − 5 < x < − 3 (D) − 3 < x < 2 (E) − 3 < x < 5 1

(C) − 3 < x < 10 ( )

1

10. If x < 5 and x > 3, then 1

1

1

(A) 3 < x < 5

(B) x < 5 and x > 3

(D) −5 < x < − 3

(E) None of the above.

1

(C) 5 < x < 3

11. If a > 0 and b < 0, which of the following is true? (A) a + b > 0 (B) a – b < 0 (D) a ÷ b < 0 (E) ab > 0

( ) (C) a2 – b2 < 0 ( )

12. If a > c and b > c, then (A) a > b

a

(C) b > 1

(B) b > c

a

(D) b < 1

(E) None of the above.

( ) x

13. Given that 1 < x < 5 and − 4 < y < 2, then the greatest value of y is 5

5

(B) − 4

(A) − 4

1

(D) − 4

(C) 2

(E) Not possible to find.

( )

14. Given that 0 < x < 1, which of the following expressions will be greatest? 3

(A) x + x2 + x3

3

(B) x

3

(C) x2 1

(E) x4 + x2 + x2

(D) x + 3x + x

( )

15. Which of the following is/are true? (II) ( −π ) 2 > (−3) 2 (I) – π > –3 (A) I only (B) II only (D) II and III only (E) I and III only 16. Solve the inequality 3 − (A) x ≥ –5

( )

2 x − 7 x + 1 3( x + 4) ≤ − . 4 2 4

(B) x ≥ 29

Teachers’ Resource NSM 3

(III) 2 2 > ( −3) 2 (C) I and II only

(C) x ≤ 28

(D) x ≤ –5

(E) x ≥ 9

(

© Oxford University Press

)

Answers 1. B 5. A 9. E 13. E

2. B 6. D 10. C 14. C

Teachers’ Resource NSM 3

3. D 7. D 11. D 15. C

4. B 8. B 12. E 16. B

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Secondary 3 Mathematics Test Chapter 3 Linear Inequalities 1. Fill in the blanks for each of following: then ______ ≤ x ≤ ______ . (a) If –6 ≤ 2x ≤ 8 x then ______ ≤ x ≤ ______ . (b) If −2 ≤ ≤ 4 2 (c) If –9 ≤ –3x ≤ 15 then ______ ≤ x ≤ ______ . x then ______ ≤ x ≤ ______ . (d) If − 1 ≤ − ≤ 3 2

[1] [1] [1] [1]

2 1 ≤ 2 k ≤ 17 , write down 3 3 (a) the smallest integer value of k, (b) the largest prime value of k, (c) the largest rational value of k.

2. Given that − 4

[1] [1] [1]

3. Given that x is an integer, find the largest possible value of x which satisfies the following inequality: 2 6 − x ≥ ( x − 8) 3

4. Given that 4 x − 3 ≤

1

3 (a) a rational number, (b) a prime number.

( 2 x + 22 ) , state the greatest possible value of x if x is [2] [1]

5. List all the possible integer values of x such that 2 ≤ x < 14 and 15 ≥ x > 8.

6. Solve the inequality

[2]

x−2

<

3x + 1



15 − 2 x

[3]

and illustrate your solution with a number line.

[4]

7. Given that x is an integer such that x + 3 < 15 < 4x – 3 , find the largest and smallest possible values of x.

[3]

4

Teachers’ Resource NSM 3

5

5

© Oxford University Press

8. Solve the inequality 5(2x – 3) ≥ 14 – x and state the smallest possible value of x if x is an integer. [3]

9. Given that

3x



1

≤ 3x − 9

4 8 (a) x is an integer, (b) x is a prime number.

10. Solve the inequality

11. Solve the inequality

4

3

2

, state the smallest value of x when [2] [1]

x−3

2

1



x −5 6

<

2

.

3

[3]

( x − 7 ) > 6 − 2 x and show your answer on a number line.

12. (a) Find the smallest integer x such that −

1

x < 3. 4 (b) Find the largest prime number y such that 5y ≤ 45 + 2y .

13. Solve the inequality

14. Solve the inequality

x−3 4 2 3



x−5 7

( x + 2) ≥

[2] [2]

> 4.

5 6

[3]

[3]

and illustrate your answer on a number line.

[3]

15. Given that 3x + 2 ≤ 24 , solve the inequality and state (a) the greatest integer value of x, (b) the greatest prime number x.

[4]

16. Find the largest prime number k for which 3k + 2 < 95 .

[2]

17. Solve the following inequality: 5(x + 2) < 3(x-1) + x .

[2]

18. Solve the following inequalities, illustrating each solution with a number line. (a) 2x + 9 ≥ 5 (b) 2(3 + x) < 6x – 9

[2] [2]

19. Solve the following inequality: 9 −

Teachers’ Resource NSM 3

3 2

x ≥ 12

[2]

© Oxford University Press

20. (a) Solve the inequality

5x − 2 −3

> 2 − 3 x and indicate your answer on the number line given

below.

[3]

(b) If x is a prime number, state the smallest possible value of x.

[1]

1 21. Given that 5(8 − 3 x ) ≤ 1 , find the smallest possible value of x if 2 (a) x is an integer, (b) x is an odd number, (c) x is a factor of 32.

[2] [1] [2]

22. Given that 17 – 4x ≤ x – 11 , find (a) the least possible value of x, (b) the smallest integer value of x.

[2] [1]

23. Solve the inequality 2 x − 1

1

1 ≥ 11 + 5 x and write down the largest integer value of x. 2 4

[3]

24. Given that 3(x + 4) ≥ 7(x – 1) – 2(x + 1) , state the greatest possible value of x if x is (a) a rational number, (b) an integer, (c) a prime number.

[2] [1] [1]

25. Solve the inequality5(2x – 3) > 6(3x – 1) . State the largest possible value of x if x is an integer.

[4]

26. Solve the following inequality and illustrate your answer with a number line

2x + 3 3

<

4x − 9 5

.

[3]

27. List all the possible values of x, where x is a prime number and satisfies both of the following inequalities: 2x > 19, 3x + 2 < 81.

Teachers’ Resource NSM 3

[3]

© Oxford University Press

28. Solve the following inequalities and illustrate your answers with a number line respectively. (a) 5 – 2x ≥ 3x + 14 1 1 (b) − ( 2 x − 3) ≤ ( x + 7 ) 3 3

30. Given that 3 x + 5 ≤

2x + 5



[4]

1

( 2 x + 48) , find 3 (a) the greatest rational value of x, (b) the greatest value of x, if x is a prime number.

31. Given that

[3]

2 − 3x

1 ≥ 3 − 2 x and draw a number line to illustrate your answer. 2 2 If x is an integer, state the smallest possible value of x.

29. Solve the inequality

[2]

3x + 2

+

4x − 3

, solve the inequality and state 3 4 3 (a) the greatest rational number x, (b) the greatest value of x if x is a perfect square.

32. Solve the following inequalities: (a) 5 – 3x ≤ 4x + 12 3 2 1 1 (b) − x > 1 x + 5 3 4 6

33. Given that –5 ≤ x ≤ –1 and 1 ≤ y ≤ 4 , find (a) the greatest possible value of 2x – y, 2x (b) the least possible value of . y

34. Given that x and y are integers and 1 ≤ x ≤ 6 and –5 ≤ y ≤ 4 , find 2 2 (a) the greatest possible values of (i) x – y (ii) x – y y (b) the least possible values of (i) x + y (ii) x 35. x and y are integers such that –5 ≤ x < 4 and –5 ≤ y ≤ 5. Calculate (a) the greatest value of 2x – y , (b) the least value of 2xy , 2 2 (c) the greatest value of x + y , 2 2 (d) the least value of 2x – y .

Teachers’ Resource NSM 3

[2] [1]

[2] [2]

[2] [3]

[1] [2]

[2] [3]

[1] [1] [1] [1]

© Oxford University Press

36. If 0.5 ≤ x ≤ 5 and –2 ≤ y ≤ 2 , find the greatest and least values of y (a) 2x – y (b) x

[4]

37. Two sides of a triangle are 10 cm and 6 cm and the third side has a length of x cm. Write down an inequality that must be satisfied by x. [2]

38. A fruit-seller bought a case of 113 oranges for $22.50. If he sells each orange for 40 cents, what is the least number of oranges that he must sell in order to make a profit of not less than $6? [3]

39. The perimeter of an equilateral triangle is not more than 90 cm. What is the largest possible side of the triangle? [2]

40.Yusof and his brother wanted to buy a present for their father. Yusof volunteered to pay $5 more than his brother. If the cost of the present was not more than $24, what was the greatest possible amount paid by Yusof? [4]

41. Mengli wants to buy hamburgers for her friends. Each hamburger costs $1.30. What is the maximum number of hamburgers she can buy with $22 and what will be the change received? [4]

42. Mani and Usha went shopping. During their shopping spree, Usha spent $25 more than Mani. Together they spent at least $120. What is the least amount spent by Usha? [4]

43. Find the odd integer which satisfies the inequalities 2x + 1 ≥ 5 and 3x + 15 > 5x – 1. [2]

44. Given that −2 ≤ x ≤ 3 and −3 ≤ y ≤ −1, calculate (a) the smallest value of x – y, (b) the largest value of

[1]

x . y

[2]

45. Given that −5 ≤ 4x + 1 ≤ 2x + 9 and −6 ≤ 2y – 2 ≤ 8, find (a) the greatest value of x – y, (b) the smallest value of (x + y) (x – y). 1

[1] [2]

1

46. Given that x is a rational number and that 2 ≤ x ≤ 39 4 , write down

(a) the greatest value of x, (b) the smallest value of x such that x is a prime number, (c) the greatest integer value of x which is exactly divisible by 2 and 5. Teachers’ Resource NSM 3

[3]

© Oxford University Press

47. Solve the inequality

x+3 2

> 2.

[2]

48. Solve the inequalities 2x

x

5

x+1 2



x+3 4

(a) 3 − 2 ≥ 6 (b)

[2] ≥

3x − 5 8

[2]

49. If 12 – 7x ≤ 5 – 2x, find the least possible value of x.

[2]

50. Solve the following inequalities and illustrate your answer on a number line. 1

(a) 3 (x + 2) ≤ 3x + 2 (b) 7 + 3x < 5 – x ≤ 6 – 3x

[2] [3]

1

51. Given that −2 ≤ x ≤ 3 2 and 2 ≤ y ≤ 5, (a) list the integer values of x, (b) write down the largest rational value of x, (c) calculate the smallest possible value of (i) (x – y)2 (ii) x2 – y2 (iii)

[1] [1] [1] [1]

2x y

[1]

52. Given that −5 ≤ 4x – 1 ≤ 2x + 7 and −6 ≤ 3y ≤ 15, find (a) the greatest possible value of x + y (b) the smallest possible value of x – y (c) the greatest possible value of x2 – y2 (d) the smallest possible value of x2 + y2

[6]

53. A woman buys x oranges at 50 cents each and (2x + 1) pineapples at $1.20 each. If she wishes to spend not more than $25 on these produce, (a) form an inequality in x, and [2] (b) find the largest number of x. [1] 54. Given that 1 ≤ x ≤ 8 and −5 ≤ y ≤ 1, find (a) the greatest possible value of x – y (b) the smallest possible value of x2 + y2

[1] [2]

1

55. Given that 3x ≤ 42 2 , state the largest possible value of x if (a) x is an integer, (b) x is a prime number, (c) x is a real number.

[1] [1] [1]

56. Find the smallest integer value of x that satisfies the inequality 2x – 3(1 – x) > 7.

Teachers’ Resource NSM 3

[3]

© Oxford University Press

57. Given that 3 ≤ x ≤ 5 and −1 ≤ y ≤ 3, find (a) the largest value of 3x – y, (b) the smallest value of

1 x

+

[1] 1 y

.

[2]

58. Find the integer values of x for which 21 < 3(x + 1) < 30. 3

[2]

2

59. Solve the inequality 4 x − 3 (1 – x) < 7.

[2] 22

60. Find the possible values of x for which x is a positive integer and 3.5 < 7 x2 < 143. [3]

61. Solve each of the following inequalities, illustrating your answer with the number line. [36] (a) 2x – 3 > 4 (b) 3x + 4 < 7 (c) 7x – 12 < 9 (f) 5x – 4 ≤ 21 (d) 4x + 1 > –3 (e) 3x + 2 ≥ 11 (g) 3x + 24 ≥ 7x (h) 5x – 12 ≥ 2x (i) 8x – 4 ≥ 3x + 16 (l) 15– 3x < x + 4 (j ) 7x – 13 > 3x – 5 (k) 6x – 9 ≤ 2x – 7 x + 1 2x − 7 < 10 15 2x 6 x 2 (p) + > − 35 7 5 5

(m)

x −3 x −7 > 21 14 1 x −1 2x 1 (q) + > + 2 2 7 14

(n)

x 13 x 1 + ≤ − 11 44 5 11 x 1 13 13 − 5 x (r) − > − 3 5 30 10

(o)

1 2

62. Given that x ≥ 9 , state the smallest possible value of x if (a) x is a prime number, (b) x is a mixed number, (c) x is an integer. 63. Given that 4x – 3 ≤ 18, find the greatest possible value of x if (a) x is an integer, (b) x is a rational number, (c) x is a prime number.

[3]

[4]

64. Find (a) the smallest integer x such that 7x > 18, 3x < 18, 4 2 (c) the smallest mixed number x such that x ≥ 13, 5 1 2 (d) the largest rational number such that x − 5 ≤ 14 − x . 3 5

(b) the largest prime number x such that

Teachers’ Resource NSM 3

[5]

© Oxford University Press

65. An apple costs 45 cents while oranges are 35 cents each. A man wishes to buy 27 apples and 46 oranges. What is the minimum number of $10 notes he must bring to make the purchase? [3] 66. A woman is organising a barbecue party for her friends. She intends to buy 8 kg of beef costing $ 9.80 per kg, 12 kg of mutton costing $12.50 per kg, 16 kg of chicken wings costing $4.20 per kg and 17 kg of prawns at $15.50 per kg. What is the minimum number of $50 notes she must bring along for all these purchases? [4] 67. A music shop is having a sale and each compact disc is priced at $12.49. A man has $97 in his pocket. What is the maximum number of compact discs that he can buy? [3] 68. Solve the following inequalities. (a) x + 5 < 5x – 9 (b) 2(3x – 1) ≤ (4 – x) 4 x+3 x−1 3x + 8 2x x (d) 2 − 4 ≤ (c) 3 − 2 ≤ 5 8 (e) x + 17 < 3(x + 5) < 45 (f) 3x – 10 > 4x – 19 > x + 2 2x + 2 x−1 ≤4 (g) 4x – 4 > 3x > 4x – 6 (h) 3 < 5 69. Given that −5 ≤ x ≤ − 1 and 1 ≤ y ≤ 6, find (a) the greatest possible value of 2x – y, 4x, (c) the least possible value of

y , x

[16]

(b) the greatest possible value of y – (d) the least possible value of

x . y

[8] 70. List the integer values of x, where x is prime, which satisfy both the following inequalities 2x > 14, 3x – 2 < 67. [3] 71. List the integer values of x which satisfy 3x – 5 < 26 ≤ 4x – 5.

[3]

72. Find the integer x for which 3 < x – 3 < 7 and 11 < 2x + 3 < 20.

[3]

73. Solve the inequality 3x + 5 ≤ 4x + 1 ≤ 3x + 8.

[3]

74. Given that − 7 < 2x ≤ 8, write down (i) the greatest integer value of x,

[4]

Teachers’ Resource NSM 3

(ii) the smallest integer value of x.

© Oxford University Press

Answers 1. (a) –3, 4

(b) –6, 8

2. (a) –2

4. (a) 3

(b) 7

1

(c) –5, 3 (c) 8

(d) –6, 2

2 3

(b) 7

10

5. 9, 10, 11, 12, 13 6. −2 < x ≤ 2

4 5

7. Largest possible value of x = 11 Smallest possible value of x = 5 8. x ≥ 2

7 11

9. (a) 5

, 3 (b) 5

10. x < 7

11. x > 4 12. (a) 0

(b) 13

13. x > 37

2

14. x ≥ −

3

3

4

15. (a) 7

(b) 7

16. 29 17. x < –13 (b) x > 3

18. (a) x ≥ –2

3 4

19. x ≤ –2

20. (a) x > 1 21. (a) 3

(b) 2 (b) 3

(c) 4

Teachers’ Resource NSM 3

© Oxford University Press

22. (a) 5

3

(b) 6

5

23. x ≤ 4

1 4

24. (a) 10

25. x < −1

;

4

1

(b) 10

2 1

8

(c) 7

, -2

26. x > 21

27. 11, 13, 17, 19, 23 28. (a) x ≤ −1

4

(b) x ≥ −1

5

1 3

29. x ≥ 5 ; 5 30. (a) 9

31. (a) 1

(b) 7

9 17

(b) 1

32. (a) x ≥ –1

(b) x <

33. (a) –3

(b) –10

34. (a)(i) 11 (b)(i) –4 35. (a) 13

26 115

(ii) 36 (ii) –5 (b) –50

36. (a) 12, –1

(c) 50

(d) 50

(b) 4, –4

37. 4 < x < 16 38. 72 39. 30 cm 40. $14.50 41. 16 ; $1.20 42. $72.50

43. 3, 5, 7 Teachers’ Resource NSM 3

© Oxford University Press

44. (a) −1

(b) 2

45. (a) 6

(b) −25 1

46. (a) 39 4

(b) 2

(c) 30

47. x > 1 48. (a) x ≥ 5

(b) x ≤ 3

2

49. 1 5 1

1

50. (a) x ≥ − 2

(b) x ≤ − 4

51. (a) −2, −1, 0, 1, 2, 3

(b) 3 2

(c) (i) 0

(ii) −25

52. (a) 9

(b) −6

(c) 16

(d) 0

53. (a) 2.9x ≤ 23.8

(b) 8

54. (a) 13

(b) 1

55. (a) 14

(b) 13

1

(iii) −2

1

(c) 14 6

56. 3 4

(b) − 5

57. (a) 16 58. 7, 8 7

59. x < 5 17 60. 2, 3, 4, 5, 6

61 (a) x > 3 (f) x ≤ 5 (k) x ≤

1 2

1

(g) x ≤ 6 (l) x > 2

2

(p) x < 8

(b) x<1

4 5

(q) x >

Teachers’ Resource NSM 3

3

4 1 3

(c) x<3

(d) x>–1

(e) x ≥ 3

(h) x ≥ 4

(I) x ≥ 4

(j) x>2

(m) x>17

(n) x<15

(o) x ≥ 3

13 24

(r) x<4

© Oxford University Press

1 2

62. (a) 11

(b) 9

63. (a) 5

(b) 5

64. (a) 3

(b) 23

1 4

(c) 10 (c) 5 (c) 32

1 2

(d) 25

10 11

65. 3 66. 12 67. 7 68. (a) x > 3

1 2

(e) 1 < x < 10 69. (a) −3

(b) x ≤ 1

4 (c) x ≤ 4 5

(d) x ≥ 6

(f) 7 < x < 9 (g) 4 < x < 6 (h) − 11 < x ≤ 9 (b) 26

(c) −6

(d) −5

70. 11, 13, 17, 19 71. 7, 8, 9, 10 72. 7, 8 73. 4 ≤ x ≤ 7 74. (i) 4

(ii) − 4

Teachers’ Resource NSM 3

© Oxford University Press

Chapter 4

Secondary 3 Mathematics Chapter 4 Coordinate Geometry IT Activities Geometer’s Sketchpad WS 3-4-1 using GSP - Page 83

j = 7.1 cm Slope j = 1.00 k: y = -x + 5.00 G: (2.5, 2.5) l: y = x

E

D

m

l k G

j

C

A

I

B

F

1. Select Create Axes and then Show Grid from the Graph Menu. A Grid showing two points A at (0, 0) and B at (1, 0) will be shown. 2. Select and drag the point A if you want to change the position of the axes. Dragging the point B will change the scale of the axes. Teachers’ Resource NSM 3

© Oxford University Press

3. Use to draw a line segment joining the points C(1, 1) and D(5, 2). Using and select line segment CD, you can measure the Length and the Slope of the line segment from the Measure Menu. 4. To find the equation of the line you need to use to draw line(one with double arrow) and select Equation from Measure Menu. Use to draw a line starting from the point (1. 3) and ending at the point (6, 1). 5. You can use to drag the point E and observe the change in the displayed equation. Do the same for the point F. 6. To find the point of intersection of the two lines, use choose Coordinates from Measure Menu. 7. Use

to mark the point as G and

to drag point C and observe the change in the coordinates of G.

Teachers’ Resource NSM 3

© Oxford University Press

WS 3-4-2 using GSP - Page 84 DE: y = 0.7x + 5.0 FG: y = -1.5x - 1.5 E: (-3, 3) D

D: (0, 5) G: (1, -3) F: (-1, 0) E

F

O

B

G

1. Use Graph Menu to select Create axes and then Show grid 2. Re-label the origin as O with . Double click on point and a Re-label panel will appear. Type O at the blank and click OK. 3. Use

to select 2 points and label them as D and E

4. Use

(double arrow head) to draw a line passing through the points D and E

5. Use

to select line DE and choose Equation from the Measure Menu.

6. Use

to select D and E and choose Co-ordinates from Measure Menu

7. Choose two more points by using F and G.

and label them as F and G. Draw the line through

8. Use

to select line FG and Equation from Measure Menu to find its equation.

9. Use

to drag the point D and see how the equation changes.

10. Repeat the dragging with other points and see the effect for yourself. Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 4 Coordinate Geometry GENERAL NOTES Teachers should revise with pupils the naming of coordinate points on a graph. It is not uncommon to find even Secondary 4 pupils being confused by the naming of coordinate points. Many pupils have difficulty distinguishing equations parallel to the x- and y- axes. Many incorrectly refer to the equation of the x-axis as x = 0 and the equation of the y-axis as y = 0. Constant revision over the year may help to correct this common mistake. To facilitate easy understanding of a problem in coordinate geometry, teachers may insist that pupils draw a sketch of the points for every question they are attempting. The subtopic on mid-point of two end points is moved to the additional mathematics syllabus. Although the concept of parallel lines implying that the gradients are the same is not mentioned in the syllabus, it is still in the additional mathematics syllabus. Teachers can mention this fact to the pupils as many pupils nowadays take additional mathematics.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: 35 min Marks: 9

Secondary 3 Multiple-Choice Questions Chapter 4 Coordinate Geometry 1. Find the equation of the straight line that passes through the points A(0, −3) and B(−1, 0). (B) y = −3x – 3

(A) y = 3x – 3 1

1

(C) y = − 3 x – 3

(E) y = −x – 3

(D) y = 3 x – 3

( )

2. A straight line has a gradient of 2 and passes through the point (3, 4). The equation of the straight line is (A) 2x – y – 2 = 0 (B) 2x – y + 2 = 0 (C) x – 2y – 2 = 0 (D) x – 2y + 2 = 0 (E) 2x – y – 10 = 0 ( ) 3. Which of the following lines is parallel to the line 4y = 6x + 5? (A) 2y + 3x = 5 (B) 2y – 3x = 57 (C) y = 6x + 5 (D) 4y + 6x = 13 (E) none of the above

( )

4. The length between points (2, −5) and (−1, −2) is (B) 10 (C) 5 2 (D) (A) 3 2

( )

58

(E) 2 13

5. The equation x = 15 represents a straight line (A) parallel to the x-axis. (B) parallel to the y-axis. (C) passing through the origin. (D) having a gradient of 15. (E) having a y-intercept of 15.

( )

6. The equation y + 15 = 0 represents a straight line (A) parallel to the x-axis. (B) parallel to the y-axis. (C) passing through the origin. (D) having a gradient of 15. (E) having a gradient of −15.

( )

7. In the diagram, the line l has the equation 2y = mx + 2c. The length of OA is (A) 2 units (B) 1 unit (C) 2c units (D) c units

m

(E) 2 units ( )

Teachers’ Resource NSM 3

© Oxford University Press

8. The distance between the points P(a, 5) and Q(−3, 2) is 5 units. The value of a must be (A) 1 (B) −7 (C) 7 (D) 1 or −7 (E) 7 or −1 ( ) 9. The equation of the line AB in the diagram is (A) x + 3y – 3 = 0 (B) x – 3y – 3 = 0 (C) 3x + y – 3 = 0 (D) 3x – y – 3 = 0 (E) x – 3y + 3 = 0 ( )

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. B 6. A

2. A 7. D

Teachers’ Resource NSM 3

3. B 8. D

4. A 9. B

5. B

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

)

Date: ____________ Time allowed: min Marks:

Secondary 3 Mathematics Test Chapter 4 Coordinate Geometry 1. If (3, 7) is a point on the line kx + 3y = 37, find the value of k. Using separate diagrams, sketch the graphs of (a) y = kx2

[2]

k

(b) y = x , where k is a positive constant and x is not equal to zero in (b).

2. A straight line passes through the points (0, 5) and (2, 13). Find (a) its gradient, (b) its equation.

[4]

[1] [2]

3. The coordinates of P, Q and R are P(8, 12), Q(9, 4) and R(−5, −4) respectively. M is the midpoint of QR. Calculate the distance of PM. [4]

4. Find the equation of the straight line (a) passing through the point (5, 7) and parallel to the x-axis. (b) passing through the point (−2, −5) and parallel to the y-axis.

[1] [1]

5. Find the equation of the straight line l which passes through the points (0, 1) and (−2, 4). If the point (k, 9) lies on l, find the value of k. [3] 6. A straight line with gradient m and y-intercept c passes through the points (2, 5) and (− 4, 9). Find the values of m and c. [3] 7. The points (3, −2), (−2, 5) and (5, k) lie on a straight line. Find the value of k. x

[2]

y

8. The equation of the line l is 3 + 4 = 1. (a) Find its gradient. [1] (b) The line cuts the x-axis at A and the y-axis at B. Find the area of ∆OAB where O is the origin. [2] 9. Find the equation of the straight line which passes through the point (−2, 4) and is parallel to the line y = 2x + 5. [3] 10. Find the equation of the straight line which has a gradient of 2 and which passes through the point (2, 1). [3]

Teachers’ Resource NSM 3

© Oxford University Press

11. (a) Given that the line 2x + 3y = k passes through the point (2, − 4), find k. (b) The line 5x + 7y = 15 is parallel to the line 2y = kx + 13. Find the value of k.

[1] [2]

12. The point (−2, t) lies on the line 3y + 2x = 7. Find the value of t.

[2]

13. The equation of a straight line is 2x + y = 8. (a) Find the gradient of the line. (b) Given that the point (−3, k) lies on the line, find the value of k.

[1] [2]

1

14. The coordinates of the three points are A(0, 3), B(t, 0) and C(2 t, t). If AB = 2AC, find the possible values of t.

[3]

15. Given that the three points A(0, 1), B(k, 2.5) and C(2k, 4) lie on a straight line, find the value [3] of k. x

y

16. (a) Find the gradient of the line 3 + 5 = 1. [2] (b) The straight line y = mx + c is parallel to the line 3x + 2y = 13 and passes through the 1

point (1, 1 2 ). Find the values of m and c.

[3]

17. The points (2, 0) and (−2, 7) lie on the line kx + ky + 5 = 0. Find the values of h and k. [3]

18. Write down (a) the gradient of the straight line 3x + 5y = 17. [1] (b) the coordinates of the point on the line 4x – 5y = 13 which has y = −1 as its y coordinate. [1]

19. In the diagram, the coordinates A and C are (0, 6) and (5, 2) respectively. The line AC produced cuts the x-axis at B, and D is a point on the x-axis where CD is parallel to the y-axis. (a) (b) (c) (d)

Find the gradient of the line AC. Find the equation of the line AB. Find the coordinates of B. Calculate the area of ∆BCD.

Teachers’ Resource NSM 3

[1] [1] [1] [2]

© Oxford University Press

20. The diagram shows a line segment AB where A is the point (0, 4) and B is the point (3, 0). (a) Find the equation of the line AB. [2] (b) If the line AB is reflected in the y-axis, find the equation of the image of the line. [2]

21. (a) If the straight line 3y = k – 2x passes through (−1, −5), find k. [1] (b) If the gradient of the straight line (2k – 1)y + (k + 1)x = 3 is parallel to the line y = 3x – 7, find the value of k. [2] (c) Find the equation of the line joining the points A(1, 5) and B(7, 2). [2]

22. The coordinates of ∆ABC are A(− 4, 2), B(5, 0) and C(4, 4). (a) Calculate the lengths of AB, BC and AC. [3] (b) Show that ∆ABC is a right-angled triangle. [2] (c) Calculate the area of ∆ABC. [2] (d) Calculate the perpendicular length from C to AB. [2]

23. The coordinates of the points O, A and B of the parallelogram OABC are (0, 0), (6, 3) and (10, 8) respectively. Calculate (a) the mid-point of OB. (b) the coordinates of C. (c) the areas of ∆OAM, ∆OBN and the trapezium ABNM. (d) the area of the parallelogram OABC.

[1] [2] [4] [2]

24. The equation of a straight line is 2x + 5y = 20. Find (a) the gradient of the line, (b) the coordinates of the point where the line crosses the y-axis,

[1] [1] 1

(c) the coordinates of the point at which the line intersects the line x = 2 2 ,

[1]

(d) the equation of the line which is parallel to 2x + 5y = 20 and which passes through the point (−1, 7). [2]

Teachers’ Resource NSM 3

© Oxford University Press

25. l is the line passing through the point (3, 8) and parallel to the line 2x – 3y + 5 = 0. Find the equation of the line l. [3]

26. (a) Given that the points A(−2, 3), B(2, −2) and C(6, 1) are three vertices of the parallelogram ABCD, find the coordinates of the point D. [3] (b) Given also that the point E has coordinates E(5, k) and that A, B and E are collinear, find the value of k. [2] (c) Find the equation of the line passing through C and parallel to the line 5x – 7y = 84. [3] (d) Given that the area of ∆ABC is 16 units2, calculate the perpendicular distance from B to AC, giving your answer correct to 2 decimal places. [4]

27. The diagram shows part of the graph of 2

y= x−3. (a) A point P is on the curve with coordinates (−1, k). Find the value of k. [1] (b) Given that the straight line y = 2x + h passes through P, find the value of h. [1] (c) Another straight line l, parallel to y = 2x + h, passes through the point Q. Find the equation of the line l. [2]

2 28. The gradient of the line joining the points (5, k) and (k, −3) is 3 . Calculate the value of k. [3] 29. Given that the coordinates of A and B are (1, 3) and (7, 1) respectively, find (a) the gradient of AB (b) the equation of AB.

[4]

4 30. A line passes through the points (−2, k) and (5, 9). If the gradient of the line is 7 , find the value of k. This line cuts the x-axis at P and the y-axis at Q. Find the area of ∆OPQ, where O is the origin. [3] 31. (a) A straight line passes through P(1, −1), Q(4, 1) and R(k, 3). Find the value of k. (b) Find the equation of a straight line passing through the points A(4, 3) and B(0, −5). [4] 2 32. (a) Find the equation of a line which has gradient 3 and which passes through the point (−2, 5). Give your answer for the equation in the form y = mx + c. (b) Find the equation of the line on which both the points (0, 3) and (2, 5) lie. [6] 33. The straight line y = x + 2 cuts the x-axis at point A and the y-axis at the point B. Calculate the area of ∆AOB where O is the origin. [3]

Teachers’ Resource NSM 3

© Oxford University Press

34. Write down the gradient of the straight line 2x + 3y = 4 and find the equation of the line which is parallel to 2x + 3y = 4 and which passes through the point (1, 7). [4] 35. For all values of m, the line 2y = mx + 6 passes through a fixed point K. State the coordinates of K. [2] 36. Find the equation of the line parallel to 3x + 4y + 15 = 0 and passing through the point (3, 7). [3] 37. The straight line 3y = mx + c is parallel to the line 2y – 3x = 5 and passes through the point (1, 12). Find the value of m and of c. [3] x y 38. Given that line 4 − 6 = 1, find (a) its gradient, (b) the coordinates of the point at which it cuts the line x = 8. [4] 39. The lines ky – 2x + 5 = 0 and 6y – (k + 1)x – 3 = 0 are parallel. Find the value(s) of k. [2] 40. Three of the vertices of a parallelogram ABCD are A(−1, 5), B(5, 1) and C(6, −2). Find the coordinates of the fourth vertex D. [3] 41. The curve x2 + y2 – 6x – 8y = 0 cuts the x-axis at points O and A and the y-axis at O and B. (a) Find the coordinates of O, A and B. (b) Find the gradient of the line AB. (c) Write down the equation of the line AB. (d) ∆OAB is rotated through 90° clockwise about O to ∆OPQ. Write down the coordinates of P and Q. [8] 42. P, Q and R are the points (8, 3), (6, k) and (−3, −8) respectively. (a) If P, Q and R are collinear, find k. (b) With this value of k, find the ratio PQ : QR. (c) RQ is produced to T so that RQ = 2QT. Find the coordinates of T.

Teachers’ Resource NSM 3

[7]

© Oxford University Press

Answers 1.

2. (a) 4

3.

(b) y = 4x + 5

180 = 13.4 (b) x = −2

4. (a) y = 7 1

5. 2y + 3x = 2 ; k = −5 3 2

1

6. m = − 3 , c = 6 3 4

7. k = − 4 5 1

8. (a) −1 3

(b) 6

9. y = 2x + 8

10. y = 2x – 3 3

11. (a) k = −8

(b) k = −1 7

2

12. t = 3 3 13. (a) −2 1

(b) k = 14 1

14. t = 4 2 or 1 2 15. k = 3

Teachers’ Resource NSM 3

© Oxford University Press

2

1

16. (a) −1 3

(b) m = −1 2 ; c = 3

1

3

17. h = −2 2 , k = −1 7 3

18. (a) − 5

(b) (2, −1)

4

19. (a) − 5 (c) (7.5, 0)

(d) 2.5 units2

20. (a) 3y + 4x = 12

(b) 3y = 4x + 12

21. (a) −17

(b) 7

(c) 2y + x = 11

(c) 17

(d) 3.69

(b) (4, 5)

(c) 9, 40, 22

(d) 18

(d) 3.88 units

22. (a)

85 ,

(b) 5y + 4x = 30

2

17 ,

68

23. (a) (5, 4) 2

24. (a) − 5

(b) (0, 4)

1

(c) (2 2 , 3)

(d) 2 x + 5y = 33

25. 3y = 2x + 5 3

26. (a) D(2, 6)

(b) k = −5 4

(c) 7y = 5x – 23

27. (a) −5

(b) −3

(c) 3y = 6x – 4

1 28. 5

1 29. (a) − 3

(b) 3y + x = 10

1 30. k = 5, 33 56

31. (a) 7

(b) y = 7x – 5

2 1 32. (a) y = 3 x + 6 3 (b) y = x + 3 2 34. − 3 , 3y + 2x = 23 1 37. m = 1 2 , c = 9

Teachers’ Resource NSM 3

33. 2 units2

35. (0, 3) 1 38. (a) 1 2

36. 4y + 3x + 37 = 0

(b) (8, 6)

© Oxford University Press

39. 3, − 4

40. (0, 2)

41. (a) (0, 0) , (6, 0) , (0, 8) (c) 3y + 4x = 24 42. (a) 1

(b) 2 : 9

Teachers’ Resource NSM 3

1 (b) −1 3 (d) P (0, −6) , Q (8, 0) 1 1 (c) (10 2 , 5 2 )

© Oxford University Press

Chapter 5

Secondary 3 Mathematics Chapter 5 Matrices GENERAL NOTES In this syllabus, only addition, subtraction, multiplication of two matrices will be involved. The subtopic of using inverse matrix to solve a pair of simultaneous equations will be covered in the additional mathematics syllabus. The topic of using matrices to solve practical problems is brought from the additional mathematics syllabus to the ‘O’ level mathematics syllabus. Pupils are normally weak at recognising the order of a matrix and this normally leads to the error of multiplying two incompatible matrices for matrix multiplication. It is worth to emphasise the importance of first determine whether two matrices may be multiplied.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Secondary 3 Mathematics Test Chapter 5 Matrices ⎛ 2⎞

1. Given that A = ⎜⎜ ⎟⎟ and B = (–1, 4), find 3 ⎝ ⎠

(a) AB,

(b) 2BA. ⎛ − 6 − 16 ⎞ ⎟ and 9 ⎟⎠ ⎝ 13

2. Given that A = ⎜⎜

(a) 3A – 2X = B,

[4]

⎛ −1 − 5⎞ ⎟ , find 6 ⎟⎠ ⎝4

B = ⎜⎜

the matrices X and Y such that

(b) YB = A.

[5]

⎛ x⎞ ⎜ ⎟

⎛ x⎞

3. Given that (1 3) ⎜⎜ ⎟⎟ = (1 3 -1) ⎜ 2x ⎟ , find the value of x. ⎝ 3⎠ ⎜3⎟ ⎝ ⎠ ⎛ 3 4 t ⎞ ⎟⎟ ⎝ − 2 0 − 1⎠

4. Given that ⎜⎜

[3]

⎛3⎞ ⎜ ⎟ ⎛9⎞ ⎜ − 1⎟ = ⎜⎜ ⎟⎟ , find the value of s and of t. ⎜ 2 ⎟ ⎝s⎠ ⎝ ⎠

[4]

⎛ 3 0⎞ ⎛ a b⎞ ⎛ x⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ (2 1) , find the values of a, b, c and x. ⎝ −1 4⎠ ⎝ c 4⎠ ⎝ 4 ⎠

5. Given that ⎜⎜

⎛ 2x 0 ⎞ ⎟⎟ ⎝3y − z ⎠

6. Given that ⎜⎜

⎛ 3⎞ ⎛ 6 ⎞ ⎛ 2x 0 ⎞ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ and ⎜⎜ ⎟⎟ ⎝ 4 ⎠ ⎝11⎠ ⎝3y − z ⎠

[4]

⎛ 5 ⎞ ⎛ 10 ⎞ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , find the values of x, ⎝ −15 ⎠ ⎝ −15 ⎠

y and z.

[3] ⎛ 2 0⎞ ⎛ x ⎞ ⎛ 8 ⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , find ⎝ 3 4 ⎠ ⎝ y ⎠ ⎝16 ⎠

the values of 4x – y.

⎛ a − 2 ⎞ ⎛ − 3⎞ ⎛ 7 ⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , ⎝ − 4 1 ⎠ ⎝ b ⎠ ⎝15 ⎠

find the value of a and of b.

7. Given that ⎜⎜

8. Given that ⎜⎜

0 ⎞ ⎛3 0⎞ ⎛ k 0 ⎞ ⎛ 6 ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , find ⎝ 5 2 ⎠ ⎝ 3 3h ⎠ ⎝ m 2h − 7 ⎠

9. Given that ⎜⎜

Teachers’ Resource NSM 3

[2]

the values of h, k and m.

[3]

© Oxford University Press

⎛ − 1 − 1⎞

⎟⎟ , find the matrices A 2 and A 3 . Hence, write down the 10. Given that A = ⎜⎜ ⎝3 3⎠ 5 [4] matrices A and A 7 . ⎛ x⎞

11. Given that x and y are positive integers and that (x y ) ⎜⎜ ⎟⎟ = 13, find the possible ⎝ y⎠ [3] values of x and y.

12. Solve the following matrix equations. ⎛1 3 2 ⎞ ⎟⎟ (a) ⎜⎜ ⎝ 0 1 − 2⎠ ⎛ x⎞

⎛1⎞ ⎜ ⎟ ⎛5⎞ ⎜ a ⎟ = ⎜⎜ ⎟⎟ ⎜ 2⎟ ⎝b⎠ ⎝ ⎠

⎛ 2 1⎞ ⎛ 2⎞

⎛ 3⎞

⎟⎟ ⎜⎜ ⎟⎟ + ⎜⎜ ⎟⎟ (b) ⎜⎜ ⎟⎟ = ⎜⎜ ⎝ y ⎠ ⎝ 3 0⎠ ⎝ 5⎠ ⎝ 2⎠

⎛ 0 1⎞ ⎛ a − 4⎞ ⎛ 2 ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎝ − 2 0⎠ ⎝ b 0 ⎠ ⎝1 ⎛ 1 3⎞ ⎛1 − 2⎞ ⎛ 2 ⎟⎟ + ⎜⎜ ⎟⎟ ⎜⎜ (d) 3⎜⎜ ⎝ −1 2⎠ ⎝3 2 ⎠ ⎝ 3

(c) ⎜⎜

⎛ 2 0⎞ ⎛ a ⎟⎟ ⎜⎜ ⎝ 0 5⎠ ⎝ 0

(e) ⎜⎜

3⎞ ⎛ 0 ⎟+⎜ 0 ⎟⎠ ⎜⎝ 6 3⎞ ⎛ a ⎟=⎜ 0 ⎟⎠ ⎜⎝ c

− 3⎞ ⎟ 2c ⎟⎠ b⎞ ⎟ d ⎟⎠

b ⎞ ⎛⎜ 1 7 ⎞⎟ ⎛ 5 7 ⎞ 3 –⎜ ⎟= ⎟ c ⎟⎠ ⎜⎝ 3 4 ⎟⎠ ⎜⎝ 3 7 ⎟⎠

[10]

⎛1 2⎞ ⎛2 1⎞ ⎛1 4⎞ ⎟⎟ , B = ⎜⎜ ⎟⎟ and C = ⎜⎜ ⎟⎟ , ⎝3 4⎠ ⎝ 3 4⎠ ⎝3 2⎠

13. If A = ⎜⎜ (a) (b) (c) (d) (e) (f)

is A + (B + C) = (A + B) + C ? is A × (B × C) = (A × B) × C ? is A + B = B + A ? is A × B = B × A ? is A × (B + C) = (A × B) + (A × C) ? Can you give the name of this rule? is A + (B × C) = (A + B) × (A + C) ? [6] ⎛0 ⎛1 0⎞ ⎛1 1⎞ ⎟⎟ , B = ⎜⎜ ⎟⎟ , C = ⎜⎜ ⎝0 1⎠ ⎝0 0⎠ ⎝1

0⎞ ⎛0 1⎞ ⎟⎟ , work out each of the following and ⎟⎟ and D = ⎜⎜ 1⎠ ⎝1 0⎠ express your answers in terms of A, B, C and D. (b) B² (c) C² (d) D² (a) A² (f) BD (g) BC (h) CB [16] (e) DB

14. If A = ⎜⎜

⎛2 1⎞ ⎛1 3⎞ ⎛ 4 1⎞ ⎟⎟ , B = ⎜⎜ ⎟⎟ and C = ⎜⎜ ⎟⎟ to verify the distributive law of ⎝ 3 4⎠ ⎝ 4 2⎠ ⎝ 2 3⎠

15. Use the matrices A = ⎜⎜

multiplication over addition, that is, A (B + C) = AB + AC (B + C) A = BA + CA

Teachers’ Resource NSM 3

[6] © Oxford University Press

16. Solve the following matrix equations. ⎛ 2 0⎞ ⎛ a ⎞ ⎛ 6 ⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ 2 1 ⎠ ⎝ b ⎠ ⎝ 25 ⎠

(a) ⎜⎜

⎛5 6⎞

⎟⎟ = (10 55) (b) (a b ) ⎜⎜ ⎝ 0 3⎠

[4]

17. Find the unknowns in each of the following matrix equations: ⎛ 3

0⎞

⎟⎟ = (−3 6 ) (a) ( p q ) ⎜⎜ ⎝ − 4 2⎠

⎛ x 2⎞ ⎛ 4 ⎞ ⎛ − 2⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ 2 z 0 ⎠ ⎝ −1⎠ ⎝ 8 ⎠ ⎛ x 3⎞ ⎛ 4 y ⎞ ⎛1 0⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ (e) ⎜⎜ ⎝ −1 4⎠ ⎝ 1 x ⎠ ⎝ 0 1 ⎠

(c) ⎜⎜

⎛ a b ⎞ ⎛ 1 ⎞ ⎛15 ⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ 3 2a ⎠ ⎝ 4 ⎠ ⎝ 11 ⎠ ⎛3 x⎞ ⎛ x⎞ ⎛ y ⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ (d) ⎜⎜ ⎝ 5 0 ⎠ ⎝ x ⎠ ⎝ −10 ⎠

(b) ⎜⎜

⎛x y ⎞ ⎟⎟ ⎝ 8 − 4⎠

(f) ⎜⎜

⎛x y ⎞ ⎛x y ⎞ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ 8 − 4⎠ ⎝ 8 − 4⎠

[12]

18. Find the value of each of the unknowns in the following. ⎛3 2⎞ ⎛ 7 5⎞ ⎛ b c ⎞ ⎟⎟ + 3⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ (b) ⎝ 1 4 ⎠ ⎝ − 1 a ⎠ ⎝ d 2a ⎠ 1 ⎞ ⎛ 2 ⎛ x y⎞ ⎛ x 6 ⎞ ⎟ ⎟ ⎜ ⎟ ⎜ ⎜ (c) ⎜ − 4 − 6 ⎟ + 3⎜ − 1 4 ⎟ = ⎜ h 2k ⎟ (d) ⎜−3 8 ⎟ ⎜ 9 2 ⎟ ⎜ 3t 14 ⎟ ⎠ ⎠ ⎝ ⎠ ⎝ ⎝

(a) ⎜⎜

− 2⎞ ⎛ p q ⎞ ⎛1 0⎞ ⎛ 7 ⎟⎜ ⎟ ⎟=⎜ − 10 3 ⎟⎠ ⎜⎝ r s ⎟⎠ ⎜⎝ 0 1 ⎟⎠ ⎝ ⎛ 3 − 1⎞ ⎛ − 2 c ⎞ ⎛ − 2b 6 ⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ (g) ⎜⎜ ⎝ a b ⎠ ⎝ 4 − 3 ⎠ ⎝ 22 d ⎠

(e) ⎜⎜

⎛ 1 − 1 3 ⎞ ⎛ a b c ⎞ ⎛ 6 − 7 3⎞ ⎜⎜ ⎟⎟ – ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ 2 − 3 4⎠ ⎝ 4 3 9⎠ ⎝ h k t ⎠ ⎛ 1 ⎞ ⎛ 4 a b⎞ ⎜ ⎟ ⎛− 7⎞ ⎜⎜ ⎟⎟ ⎜ 2 ⎟ = ⎜⎜ ⎟⎟ ⎝ −1 a 2 ⎠ ⎜ − 3⎟ ⎝ − 7 ⎠ ⎝ ⎠

⎛ a − 2 ⎞ ⎛ − 1⎞ ⎛ − 11⎞ ⎟⎟ ⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ − 5 1 ⎠ ⎝ b ⎠ ⎝ 10 ⎠ ⎛ 2 1 ⎞ ⎛ k t x ⎞ ⎛ − 7 6 − 5⎞ ⎟⎟ = ⎜⎜ ⎟⎟ ⎜⎜ ⎟⎟ (h) ⎜⎜ ⎝ − 3 h ⎠ ⎝ − 1 2 − 3 ⎠ ⎝ 5 t 3k ⎠

(f) ⎜⎜

[16]

19. Simplify each of the following: ⎛3 5⎞ ⎛ 2 3 ⎞ ⎛ 3 5 ⎞ ⎟⎟ – ⎜⎜ ⎟⎟ + ⎜⎜ ⎟⎟ ⎝ 8 4 ⎠ ⎝ 1 −1⎠ ⎝ 7 − 9 ⎠

(a) ⎜⎜

⎛ 2 3 − 1⎞ ⎛ 3 1 − 3 ⎞ ⎟⎟ – 2⎜⎜ ⎟⎟ ⎝3 2 5 ⎠ ⎝4 1 5 ⎠

(c) ⎜⎜

⎛ 2 2x ⎞ ⎛ x y ⎞ ⎛ 2x − y ⎞ ⎟⎟ – ⎜⎜ ⎟⎟ + ⎜⎜ ⎟⎟ ⎝ 3 3y ⎠ ⎝ x − y ⎠ ⎝3y x ⎠ ⎛ 2 5 ⎞ ⎛ 5 2⎞ ⎜ ⎟ ⎜ ⎟ (d) ⎜ 3 − 4 ⎟ + ⎜ 3 0 ⎟ ⎜ 7 − 5 ⎟ ⎜ −1 4⎟ ⎝ ⎠ ⎝ ⎠

(b) ⎜⎜

⎛1 7 ⎞ ⎛ 3 − 2⎞ ⎜ ⎟ ⎜ ⎟ 2 1 ⎞ ⎛ 2 −4 3 ⎞ ⎛ 3 ⎟⎟ + ⎜⎜ ⎟⎟ (f) ⎜ 6 2 ⎟ – ⎜ − 4 1 ⎟ ⎝ − 5 7 − 4⎠ ⎝ −1 − 4 − 5⎠ ⎜ 3 − 4⎟ ⎜ 3 5 ⎟⎠ ⎝ ⎠ ⎝

(e) ⎜⎜

[12]

20. Solve the following matrix equations: ⎛2 1 ⎞ ⎛3 5 ⎞ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ 4 − 3⎠ ⎝ 7 − 9 ⎠

⎛ 2 − 4⎞ ⎛1 7⎞ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ − 5 − 6⎠ ⎝9 3⎠

(a) X + ⎜⎜

(b) Y – ⎜⎜

⎛ 3 1 ⎞ ⎛ 6 − 10 ⎞ ⎟⎟ = ⎜⎜ ⎟⎟ ⎝ − 4 5 ⎠ ⎝12 3 ⎠ 7 − 9⎞ ⎛1 2 5⎞ ⎛ 4 ⎟⎟ = ⎜⎜ ⎟⎟ (e) Q + 3 ⎜⎜ ⎝ 4 − 6 7 ⎠ ⎝ − 13 12 21 ⎠

⎛5 7 ⎞ ⎛1 − 3⎞ ⎟⎟ ⎟⎟ =2 ⎜⎜ ⎝ 4 − 2⎠ ⎝3 − 4⎠ ⎛ −1 − 3 − 9 ⎞ ⎛ 7 3 − 5⎞ ⎟=⎜ ⎟ [12] (f) R – 2 ⎜⎜ 8 − 10 ⎟⎠ ⎜⎝ 8 − 9 4 ⎟⎠ ⎝5

(c) Z + 2 ⎜⎜

Teachers’ Resource NSM 3

(d) P – 3 ⎜⎜

© Oxford University Press

21. Evaluate each of the following matrix products where it exists: ⎛ 2 3 ⎞ ⎛ − 1⎞ ⎟⎟ ⎜⎜ ⎟⎟ ⎝1 4⎠ ⎝ 5 ⎠ ⎛ 2 − 3⎞ ⎛ 3 5 ⎞ ⎟⎟ ⎜⎜ ⎟⎟ (d) ⎜⎜ ⎝ 4 7 ⎠ ⎝7 9⎠

⎛ 2 1⎞ ⎛ 3 −1⎞ ⎟⎟ ⎜⎜ ⎟⎟ ⎝ 5 3⎠ ⎝ 2 − 5 ⎠ ⎛1⎞ ⎛ 2⎞ (e) ⎜⎜ ⎟⎟ ⎜⎜ ⎟⎟ ⎝ 3⎠ ⎝ 5 ⎠

⎛ 3⎞ (g) ⎜⎜ ⎟⎟ (2 4) ⎝1⎠

⎛ 2⎞ (h) (1 2 3) ⎜⎜ ⎟⎟ ⎝1⎠

⎛2⎞ ⎜ ⎟ (j) ⎜ 5 ⎟ ⎜ − 1⎟ ⎝ ⎠ ⎛2 ⎜ (m) ⎜ 3 ⎜4 ⎝

⎛ 2⎞ ⎛1 2 3 4⎞ ⎜ ⎟ ⎟⎟ ⎜ 3 ⎟ (k) ⎜⎜ ⎝7 8 9 5⎠ ⎜1⎟ ⎝ ⎠ 4 ⎞ ⎛1 ⎜ ⎟ ⎛ 1 2 4 ⎞ ⎟ (n) ⎜ − 1 − 3 ⎟ ⎜⎜ − − − 3 1 2 ⎟⎠ ⎝ ⎜4 ⎟ 2 ⎠ ⎝

(a) ⎜⎜

(1

5 7)

1⎞ ⎟ 5⎟ 2 ⎟⎠

⎛ 2 1⎞ ⎜⎜ ⎟⎟ ⎝ − 1 3⎠

(b) ⎜⎜

⎛7 9 ⎞ ⎟⎟ (1 3) ⎝ 3 − 2⎠

(c) ⎜⎜

⎛ 2⎞

(f) (1 5) ⎜⎜ ⎟⎟ ⎝1⎠ ⎛1⎞ ⎜ ⎟ (i) (3 1 −2) ⎜ 3 ⎟ ⎜ −1⎟ ⎝ ⎠ ⎛1⎞ ⎛ 2 1 3⎞ ⎜ ⎟ ⎟⎟ ⎜ 4 ⎟ (l) ⎜⎜ ⎝ 4 − 1 2 ⎠ ⎜ − 1⎟ ⎝ ⎠

[28]

22. Evaluate each of the following matrices where possible. ⎛ 2⎞ ⎛ 5⎞ (b) (1 6 )⎜⎜ ⎟⎟ (a) ⎜⎜ ⎟⎟(4 1) ⎝ 3⎠ ⎝ 3⎠

[4]

⎛ 3 0 ⎞⎛ x ⎞ ⎛ 9 ⎞ ⎟⎟⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , find the value of x + y. 23. (a) Given that ⎜⎜ ⎝ 2 3 ⎠⎝ y ⎠ ⎝12 ⎠ ⎛ 2 k ⎞ ⎛ 4 − 8⎞ ⎟⎟ is ⎜⎜ ⎟⎟ , find the value of k. (b) Given that the square of the matrix ⎜⎜ ⎝0 0⎠ ⎝0 0 ⎠

[4] ⎛ − 4⎞ ⎜ ⎟ 24. (a) Evaluate (− 2 3 1)⎜ 6 ⎟ . ⎜ 5 ⎟ ⎝ ⎠ ⎛ 2 − 3 x ⎞⎛ x ⎞ ⎛ − 8 ⎞ ⎟⎟⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , find the values of x and y. (b) Given that ⎜⎜ ⎝ − 1 2 ⎠⎝ 1 ⎠ ⎝ y ⎠

25.

⎛ 2 0⎞ ⎟⎟ and B = Given that A = ⎜⎜ ⎝ 3 4⎠

26.

⎛ 3 5 ⎞⎛ h ⎞ ⎛ 2 ⎞ ⎟⎟⎜⎜ ⎟⎟ = ⎜⎜ ⎟⎟ , find the value of h and of k. Given that ⎜⎜ ⎝ 4 8 ⎠⎝ k ⎠ ⎝ 0 ⎠

Teachers’ Resource NSM 3

[4]

⎛ x 0⎞ ⎜⎜ ⎟⎟ . Find the value of x when AB = BA. ⎝ 2 1⎠ [3] [2]

© Oxford University Press

Answers ⎛− 2 8 ⎞ ⎟⎟ ⎝ − 3 12 ⎠

(b) (20)

1 ⎛ − 17 − 43 ⎞ ⎜ ⎟ 21 ⎟⎠ 2 ⎜⎝ 35

(b) ⎜⎜

1. (a) ⎜⎜

2. (a)

⎛ 2 − 1⎞ ⎟⎟ ⎝3 4 ⎠

3. 2

4. s = -8, t = 2 5. a = 24, b = 12, c = 8, x = 36

6. x = 1, y =

7 7 , z = −1 13 13

7. 15 1 3

8. a = −4 , b = 3 3 4

9. h = − 1 , k = 2, m = 16 ⎛ − 2 − 2⎞ ⎛ − 4 − 4⎞ ⎛ − 16 − 16 ⎞ ⎛ − 64 − 64 ⎞ ⎟⎟ , A 3 = ⎜⎜ ⎟⎟ , A 5 = ⎜⎜ ⎟⎟ , A 7 = ⎜⎜ ⎟⎟ 6 ⎠ 48 ⎠ ⎝ 6 ⎝ 12 12 ⎠ ⎝ 48 ⎝ 192 192 ⎠

10. A 2 = ⎜⎜

11. x = 2, y = 3 or x = 3, y = 2

12. (a) a = 0, b = – 4 (b) a = – 3, b = 2, c = 3

(b) x = 12, y = 8 1 (d) 2

(e) a = – 2, b = 0, c = − 1

13. (a) Yes

(b) Yes

a = – 1, b = 12, c = 9, d = 15

1 4

(c) Yes

(d) No

(e) Yes, distributive law (f) No

14. (a) A

(b) B

(c) C

(d) A

(e) C

(f) B

(g) B

(h) C

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16. (a) a = 3, b = 19

(b) a = 2, b = 14

17. (a) p = q = 3

(b) a = 1, b = 3

1 2

1 2

(e) x = − , y = – 3

(d) x = y – 2

1 3

(c) x = 0, z = 1 (f) x = 5, y = − 2

1 2

18. (a) a = – 4, b = 24, c = 17, d = – 2 (b) a = – 5, b = 6, c = 0, h = – 2, k = – 6, t = – 5 2 3

(c) x = – 1, y = 1 , h = – 7, k = 3, t = 8

(d) a = 0, b = 3

2 3

(e) p = 3, q = 2, r = 10, s = 7 (f) a = 1, b = 5 (g) a = – 1, b = 5, c = 1, d = – 16 (h) h = 4, k = – 3, t = 2, x = – 1 ⎛4 7 ⎞ ⎟⎟ ⎝14 − 4 ⎠

19. (a) ⎜⎜

⎛7 7 ⎞ ⎜ ⎟ (d) ⎜ 6 − 4 ⎟ ⎜ 6 −1 ⎟ ⎝ ⎠

2+ x 2x − 2 y ⎞ ⎟⎟ ⎝3 − x + 3y 4 y + x ⎠

(c) ⎜⎜

⎛ 5 −2 4 ⎞ ⎟⎟ (e) ⎜⎜ ⎝ − 6 3 − 9⎠

⎛− 2 9 ⎞ ⎜ ⎟ (f) ⎜ 10 1 ⎟ ⎜ 0 − 9⎟ ⎝ ⎠

⎛1 4 ⎞ ⎟⎟ ⎝3 − 6⎠

(b) ⎜⎜

⎛13 5 ⎞ ⎟⎟ ⎝18 − 14 ⎠

(e) ⎜⎜

⎛13 ⎞ ⎝19 ⎠ ⎛ − 15 − 17 ⎞ ⎟ 83 ⎟⎠ ⎝ 61

20. (a) ⎜⎜

(d) ⎜⎜

21. (a) ⎜⎜ ⎟⎟ (d) ⎜⎜

⎛− 4 1 5 ⎞ ⎟⎟ ⎝ − 5 0 − 5⎠



(b) ⎜⎜

⎛ 0 − 12 ⎞ ⎟⎟ ⎝ 20 − 7 ⎠

⎛3 3 ⎞ ⎟⎟ ⎝ 4 − 3⎠

(c) ⎜⎜

1 − 24 ⎞ ⎛ 1 ⎟ − 25 30 0 ⎟⎠ ⎝

(f) ⎜⎜

(b) ⎜⎜

⎛ 8 −7 ⎞ ⎟⎟ ⎝ 21 − 20 ⎠

(c) NA

(e) NA

(f) ( 7 )

Teachers’ Resource NSM 3

⎛ 5 − 3 − 23 ⎞ ⎟⎟ ⎝18 7 − 16 ⎠

© Oxford University Press

⎛ 6 12 ⎞ ⎟⎟ ⎝2 4 ⎠

(g) ⎜⎜

⎛2 ⎜

14 ⎞ ⎟ 35 ⎟ ⎜ −1 − 5 − 7 ⎟ ⎝ ⎠

(h) NA

(i) ( 8 )

(k) NA

(l) ⎜⎜

10

(j) ⎜ 5

25

⎛3 5 ⎞ ⎜ ⎟ (m) ⎜ 1 18 ⎟ ⎜ 6 10 ⎟ ⎝ ⎠

⎛ − 11 − 2 − 4 ⎞ ⎜ ⎟ (n) ⎜ 8 1 2 ⎟ ⎜ 2 6 12 ⎟⎠ ⎝

⎛ 8 2⎞ ⎟⎟ 22. (a) ⎜⎜ ⎝12 3 ⎠

(b) (2 3)

23. (a) 5

(b) -4

24. (a) (31)

(b) x = 8, y = -6

25. x = −

⎛ 3 ⎞ ⎟⎟ ⎝ − 2⎠

1 3

26. h = 4, k = -2

Teachers’ Resource NSM 3

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Chapter 6

Secondary 3 Mathematics Chapter 6 Application of Mathematics in Practical Situations ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 132) 1 11 % improvement 9 Just For Fun (pg 151) 59 years old

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Secondary 3 Mathematics Chapter 6 Application of Mathematics in Practical Situations GENERAL NOTES Most of the topics in this chapter were formally in the Sec 1 syllabus. One big difference is that the percentage profit or loss must be qualified as whether it is based on the cost price or selling price. This is due to the fact that many companies reported their profit as percentage of their revenue, i.e. based on their sales. Other subtopics that pupils will be introduced here are the simple and compound interests, hire purchase, money exchange, taxation, interpretation of tables and charts. Money exchange is one topic that is very close to many pupils as more and more Singaporeans travel abroad. You can ask pupils to find out the various exchange rates offered by the various money changers or banks. Why is it that there is a difference between the selling and buying rate. Would it be better if the ASEAN countries adopted a common currency as the European countries have done? Will this work for the ASEAN countries? It is good to introduce students to some of the financial knowledge at this age. The following are possible projects for the pupils to work on. (a) Compare the various home loan packages offered by 6 banks for a home loan of $300 000 to be paid over 20 years. (b) Compare the various car loan packages offered by 6 financial institutions for a car loan of $50 000 to be paid over 7 years. (For brand new car) (c) Compare the various car loan packages offered by 6 financial institutions for a car loan of $50 000 to be paid over 7 years. (For used car) (d) If you have $50 000 and wish to put it into a fixed deposit at one of the banks, find out which of the banks offer the best rate. (e) We can also ask pupils to invest $100 000 on foreign currencies for six months and see who will emerge as winner. We can appoint a few group leaders for the pupils to help calculate transactions that pupils make through the months when they want to switch their investment. The following is a worksheet for reference.

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Money Exchange Each of you are to help invest $100 000 in foreign currencies over the next six months. You are to use your foresight and prediction so as to select the best currency/currencies that will add value to the original sum. The following are the rates of currencies for your reference. CURRENCY

RATE AT Oct 13 2006 Buying Selling

RATE AT Nov 23 2006 Buying Selling

INTEREST RATE

US dollar Sterling pound Australian dollar New Zealand $ Canadian dollar

1.5740 2.9260 1.1820 1.0340 1.3890

1.5920 2.9580 1.1960 1.0570 1.4050

1.5450 2.9570 1.1970 1.0340 1.3530

1.5630 2.9910 1.2110 1.0570 1.3690

5.5 4.2 5.8 6.7 5.5

Malaysian RM Euro Chinese Reminbi Thai baht Japanese Yen

0.4297 1.9760 0.1990

0.4304 1.9980 0.2030

0.4268 1.9990 0.1970

0.4273 2.0220 0.2010

3.7 4.2 5.2

0.04190 0.013196

0.04270 0.013341

0.04220 0.013232

0.04300 0.013380

7.7 0.2

You are to make careful investments based on the above information. Enter into the following table your investments based on the exchange rates quoted on (23/11/2006) and the interest rates given. CURRENCY

AMOUNT INVESTED

SING$ EQUIVALENT

INTEREST EARNED

AMOUNT AT 23/11/2006

SING$ EQUIVALENT

You may modify the above table to take in the latest figures and set your own conclusion such as the investment can only be reviewed at the end of month etc. (f)

We can also introduce pupils to the stock market by giving each of them $50 000 virtual money to invest in the Singapore stock market. Form groups of 5 pupils with a leader to decide which stock to invest and record the profit or loss made in every transaction, to include a 0.5% brokerage for every trade. They are to base their trade on the losing prices of the day by referring to the newspaper quoted prices the next day.

(g)

The interest rate charged by credit card companies for outstanding amounts due to them is at an annual rate of 24%. Get the students to work out the amount due if $5000 is not paid for 5 years.

(h)

As Singaporeans are allowed to invest their CPF money for shares and unit trusts etc, you can ask pupils to find out the percentage of people who make money investing in stock market, unit trust etc as compared with keeping their money in CPF earning 2.5% interest.

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XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

)

Date: ____________ Time allowed: 35 min Marks: 10

Chapter 6

Secondary 3 Multiple-Choice Questions Application of Mathematics in Practical Situations

1. Abel bought a mini hi-fi set for $600. He sold it to Bob at a loss of 20%. Bob sold it to Charles and made a profit of 5%. How much did Charles pay for it? (A) $456 (B) $504 (C) $684 (D) $750 (E) $756 ( ) 2. A man bought x balloons at y cents each. He sold all of them at z cents each. If x, y and z are all increased by 10%, find the percentage increase in profit. (A) 10% (B) 15% (C) 21% (D) 30% (E) 40% ( ) 3. After the price of fuel went up by 10%, a man reduced his fuel consumption by 10%. What is the percentage change in his fuel bill? (A) decreased by 1% (B) increased by 1% (C) increased by 9% (D) decreased by 9% (E) unchanged ( ) 4. The simple interest on $680 for 5 years is $119. What is the rate of interest per annum? (A) 3.5% (B) 7% (C) 14% (D) 42% (E) 49% ( ) 5. A dealer allows 30% discount on his list prices and then makes a profit of 25% on his cost price. What is the list price of a camera on which he gains $91? (A) $76 (B) $109.20 (C) $148 (D) $520 (E) $650 ( ) 6. A mixture of coffee is made of grade A and grade B coffee powder in equal parts by weight. Grade A coffee costs $20 per kg and grade B costs $40 per kg. At what price per kg must the mixture be sold to make a profit of 10%? (C) $33 (D) $36 (E) $66 ( ) (A) $30 (B) $31 7. The number of pupils in a school increases by 15% each year. If there are 1058 pupils this year, what was the enrolment for the year before last? (A) 920 (B) 800 (C) 900 (D) 1 000 (E) 1 028 ( ) 8. The length and breadth of a cube are measured 10% too big and the height is measured 10% too small. What is the resulting percentage error in the volume? (A) 30 more (B) 30 less (C) 10 more (D) 8.9 more (E) 8.9 less (

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)

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1 9. Each year a car depreciates by 22 % of its value at the beginning of the year. What 2 will be the value of a car at the end of two years if its value at the beginning of the first year is $80 000? (B) $48 050 (C) $40 000 (A) $62 000 (D) $18 000 (E) $40 500 ( )

10. A Filipino trader exported 7 908 692 pesos worth of goods to Singapore. If the exchange rate was S$4.8702 to 100 pesos, estimate how much the importer in Singapore paid for the goods in S$. (A) 40 000 000 (B) 350 000 (C) 400 000 ( (E) 320 000 (D) 4 000 000

Teachers’ Resource NSM 3

)

© Oxford University Press

Answers 1. B 6. C

2. C 7. B

Teachers’ Resource NSM 3

3. A 8. D

4. A 9. B

5. E 10. C

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

Chapter 6

)

Date: ____________ Time allowed: min Marks:

Secondary 3 Mathematics Test Application of Mathematics in Practical Situations

1. If 15 kg of rambutans cost $25.00, calculate (a) the cost of 24 kg of rambutans , (b) the quantity of rambutans (in kg) that can be bought for $30.00.

[2] [2]

2. A shopkeeper bought an article for $400. By selling it at a discount of 18% of the list 1 2

price, he made a profit of 22 % on the cost. Find the list price.

[3]

3. A car depreciates in value by 12% during the first year and by 5% of its value during each succeeding year. If its initial value was $125 000, find (a) its value at the end of three years, [3] (b) the percentage value of the initial value at the end of three years, giving your answer correct to the nearest whole number. [2]

4.(a) A shopkeeper usually sells VCD players for $360 each. He disposes of a display set 1 2

by reducing the price by 12 % . Calculate the selling price of the display set.[2] (b) When he sells the VCD player at the usual price of $360, the shopkeeper makes a 2 3

profit of 16 % . Calculate the price paid by the shopkeeper.

[2]

(c) Find the percentage profit the shopkeeper makes on the display set.

[2]

5. Peter bought some pens for $72. On checking, he found that 8 pens were defective. He sold the remaining pens at 30% above the cost price and made a profit of $16.40. How many dozens of pens did he buy? [3]

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6. In a city, electricity is charged at $0.15 per unit for the first 440 units and $0.20 for each subsequent unit. (a) In June, Mrs Foong used 640 units of electricity. What was her electricity bill for the month of June? [2] 1 2

(b) Her electricity consumption for the month of July was reduced by 22 % . What was the corresponding percentage decrease in her bill?

[3]

7. (a) A manufacturer produced 18 000 pens and sold them in packets of 5 at $1.60 per packet. Calculate the total selling price. [2] (b) The cost of production consisted of expenditure on administration, labour and materials. The cost of administration was $2 100. Labour and materials cost 15 cents per pen. Calculate the total cost of production and express the profit made as a percentage of this total cost. [4] (c) A further 45 000 of these pens were produced and sold at the same price of $1.60 1 3

per packet of 5 pens. In this case, the profit made was 33 % of the cost of producing them. Calculate the cost of producing the 45 000 articles.

[3]

8. (a) The perimeter of a quadrilateral is 132 cm and the sides are in the ratio 5:8:15:17. Calculate how much longer is the longest side when compared to the shortest side. [2] (b)

John heard the sound of a gun 3.8 seconds after it was fired. Taking the speed of sound to be 330 metres per second, calculate the distance between John and the gun, giving your answer in kilometres. [2]

9. Mrs Tay, Mrs Chen and Mdm Rosnah each decided to buy a photocopying machine that was priced at $ 6 400. (a) Mrs Tay offered her old machine in part exchange and the salesman allowed her 27

1 % off the cost of the new machine. Calculate how much more Mrs Tay had to 2

pay for her new photocopying machine. [2] (b) Mrs Chen paid for the new photocopying machine in cash and was given a discount. Given that she paid $5 488 for her new photocopying machine, calculate the percentage discount she received. [2] (c) Mdm Rosnah agreed to pay 45% of $6 400 as a deposit and the balance in equal monthly instalments over a period of two years. Given that each monthly installment is $176, calculate how much Mdm Rosnah paid for her photocopying machine altogether. [2] (d) The salesman had hoped to sell each new photocopying machine for $6 400 so that he would make a profit of 28% on the cost price. Calculate the cost price of each new machine. [2]

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10. The amounts of money Peter, Paul and Jane have respectively are in the ratio of 3:5:7. If Jane gives Paul $198, the ratio of the amounts of money Paul and Jane have becomes 7:5. How much money do Peter, Paul and Jane have altogether? [3]

11. A bicycle shop bought 20 bicycles for $4 000. On checking, the shopkeeper found that 5 of the bicycles were slightly damaged. He sold each of the remaining bicycles at the normal selling price and each of the slightly damaged bicycles at

3 4

of the

normal selling price. What was the normal selling price of each bicycle if he made 35% profit on the whole transaction? [4]

12. In a trapezium, the ratio of the lengths of the two parallel sides is 3:2. While keeping the height of the trapezium constant, the length of the shorter parallel side is increased by 30% and the length of the longer side is decreased by 30%. What is the percentage increase or decrease in the area of the trapezium? [4]

13. The selling price of a television set is $854. Mr Koh paid cash for a set and was given 10% discount. Mr Chow bought a set from the same shop by installments and was charged 12% more than the selling price. Find the difference between the prices Mr Koh and Mr Chow paid for their television sets. [3]

14. A credit card company charges 2.5% interest per month on amounts not paid in previous months. If Mr Lee pays off $145.00 of his Novmber account of $336.82, how much interest charges will be added to his December account? [2]

15. John has a passbook account which earns him 2.5% per annum for minimum monthly balances up to $5 000 and 3.25% per annum for balances over $5 000. Calculate the December interest John receives if the minimum monthly balances in the 6 months up to December were: $5 428, $4 906, $4 269, $5 548, $4 946 and $5 967. [5]

16. A 29-inch colour television set is advertised at $1 999 at full price or $67.50 per month, (a) If $67.50 per month is the only amount to be paid, how many months approximately will it take to pay off the television set? [2] (b) If the actual terms stated are a 10% deposit and 36 monthly payments of $67.50, how much is the total cost of the television set? [3] (c) How much more than the full price should be paid to buy the television set on terms? [1]

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17. Payroll tax is due from companies paying wages. It is calculated as follows: 1 2

4% of payroll for amounts up to $500 000 and 5 % of payroll for amounts greater than $500 000. Calculate the payroll tax due on the following payrolls: (a) $357 000 (b)$950 000

[2]

18. Mortgage duty on money borrowed to purchase a property is calculated as follows: $75 on the first 150 000, plus 0.6% of the remaining amount. Calculate the mortgage duty payable on the following loans: (a) $125 000 (b) $560 000 [3]

19. The rate of commission on the sale of a house is 4% on the first 150 000, 2% on the 1 2

next 450 000, 1 % on the next 400 000 and 1% thereafter. A real estate agent sells two properties during the month of June with values of $587 500 and $1 209 500. (a) Calculate the commission due on each property. [4] (b) What was the total commission received from the sale of the two properties? [1] (c) If the agent receives 25% of the total commission received from the sales, how [2] much does the agent earn in June?

20. A man invests a sum of money at simple interest. Each year he receives $128 interest on the amount invested. When the rate of interest rises by 0.75%, the annual interest is raised to $140. Calculate the sum of money invested and the new percentage rate of interest. [5]

21. Coffee powder costing $9 per kg is mixed with coffee powder costing $13.50 per kg. The mixture is sold at $12 per kg, thereby making 20% profit. Find the ratio in which the two types of coffee powder are mixed. [4]

22. A shopkeeper sold an article for $160 making a 20% loss. How much must the shopkeeper sell the article to make a profit of 20%? [2]

23. Sugar costing $1 per kg is mixed with sugar costing $1.20 per kg in the ratio 3:1. Find the selling price per kg of the mixture to make a 20% gain. [3]

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24. Peter has $30 000 for investment. He can choose to deposit the sum of money in the 1 2

bank which pays a simple interest of 7 % per annum or invest in a building society which pays simple interest at a rate of $7.50 for every $1 000 invested per month. Find the difference in interests paid by the bank and the building society after 1 year. [3]

25. Mr Kwan borrowed from a finance company to buy a second-hand car. He pays back the loan through monthly installments for a period of 4 years. In the first year, each monthly instalment is $1 000. For each subsequent year, the monthly installment is reduced by 10% from the previous year. Find the amount of money Mr Kwan paid for the car. [4]

26. Three persons, A, B and C, enter into a business together by contributing $50 000, $45 000 and $60 000 for periods of 10 months, 12 months and 8 months respectively. At the end of the year, the gross profit is $100 000 and the expenses amount to 24% of the gross profit. The net profit is shared among A, B and C in proportion to their contributions. Find the profit A receives. [5]

27. A shopkeeper bought a watch for US$60 and sold it for S$102.60. Find his percentage profit. (Take US$1=S$1.425).

[3]

28. Mr Beaver travels from A to B on a bus at a speed of 40 km/h and then walks from B to C at a speed of 5 km/h. Given that the distance between A and C is 55 km and he takes 4 hours for the whole journey, find the ratio of the distance between B and C. [4]

29. It takes 3 men and 5 women to complete a job in 17 days and it takes 5 men and 3 women to complete the same job in 15 days. What is the ratio of the work rates of a man and a woman? [5]

30. It takes 40 workers to complete half of a certain job in 15 days. If the remaining job needs to be completed in 12 days, how many workers need to be deployed? [2]

31. Raymond drives from Town A to Town B, 120 km apart, at an average speed of 50 km/h. Find his average speed on the return journey if the round trip takes 5 hours and 24 minutes altogether. [2]

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32. Mrs Chua makes stuffed toys and is paid according to the following differential rates: 0-80 toys $3.10 per toy 81-150 toys $3.75 per toy 151-200 toys $4.60 per toy 201(or over)toys $5.80 per toy During a month when Mrs Chua makes 242 toys, how much does she earn? [3]

33. Simon places $3 684 in an investment account earning 8.25% per annum from May 28th to August 27th (including those days). Calculate the interest earned. [3]

34. (a) A train leaves Town A at 09 00 hours and is scheduled to reach Town B at 12 30 hours. What is its average speed if the distance is 273 kilometres? [2] (b) On a certain day, the train travels at this speed for 2 hours and is then delayed for three-quarters of an hour. If its average speed is 60 km/h for the rest of the journey, when does it arrive at Town B? [3]

35. The daily wages of a skilled worker, Kevin, and an apprentice, John, were $45 and $18 respectively. Working separately, Kevin received $900 when he had completed a piece of work and John received $540 when he had finished the same type of work. If they did the work together, and assuming that they were working at their own individual rates, how much would each receive when the work was completed? [5]

36. An alloy of zinc and tin contains 33% of zinc by weight. Find the weight of zinc which must be added to 600 kg of this alloy if the final percentage of tin is to be 33

1 . 3

[4]

37. In what proportion must a chemist mix two solutions of a certain chemical which cost him $24 and $36 per litre respectively so that by selling the mixture at $35 per litre, he is able to make 25% profit on his outlay? [3]

38. Goods in a shop are marked at 35 % above the cost price. What profit per cent is made if 20 % is taken off for cash? What is the greatest percentage that can be taken off without causing a loss to the shopkeeper? [5]

39.During a sale, a shopkeeper allows customers a discount of 0.175 in the dollar on the marked price which originally gave him a 40% profit. What does the customer pay now for goods which cost the shopkeeper $1 400? [3]

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40. (a) Find a man’s taxable income if he paid $1 567.50 in tax when the income tax was 1 levied at 12 %. 2 (b) If S$1 = US$0.56 and S$1 = M$1.57, find how many Malaysian ringgits can be exchanged for US$600. Give your answer correct to the nearest dollar. [4]

41. (a) A man buys a book for $12. His advertised selling price is 25% higher, but he gives a discount of 12% to schools. What is the selling price of the book to schools? (b) A salesman receives a basic salary of $550 and commission of 4% of the value of goods sold in excess of $4 500. Find his income in a month when he sells goods worth $18 000. [4] 42. Mr. Chen borrows a sum of money for 5 years. For the first 3 years, the simple interest, at a rate of 8% per annum, amounts to $3 600. For the next 2 years, the simple 1 interest is 10 % per annum. Calculate 2 (a) the amount of money he has borrowed, (b) the amount he has to pay back altogether at the end of 5 years. [4]

43. (a) A man spends 10% of his monthly income on rent, 15% on food, 12% on clothes, 8% on income tax, 21% on other expenses and saves the rest. Given that he saves $1 292 a month, find his monthly income. (b) The value of a car depreciates each year by 15% of its value at the beginning of the year. If a brand new car costs $56 000, find its value at the end of 4 years correct to the nearest 100 dollars. [4] 44. A travelling salesman receives a basic salary of $800 a month and a commission equal to 4% of the value of goods sold plus a car allowance of 60¢ per km. (a) Find his income for a particular month when he sells goods worth $13 500 and travels 800 km. (b) The next month, he travels 996 km and receives a total income of $1 970. Calculate the percentage increase in the value of goods sold. [4] 45. (a) Mr Chen is entitled to a tax-free allowance of $16 000 and he pays tax at 12% on his income over that figure. Calculate how much he has to pay if his income is $38 000. (b) Mr Lin is entitled to a tax-free allowance of $13 000 and he pays tax at 14%. Find his income if he pays $4 060 in tax. [4] 46. A manufacturer knows that 6% of the light bulbs he makes are defective. Find the number of bulbs he must produce in order to obtain 611 light bulbs which are not defective. The manufacturing cost for the light bulbs is $586.56. If he sells the non-defective light bulbs at a profit of 25%, find the selling price of each light bulb. [4] Teachers’ Resource NSM 3

© Oxford University Press

3 1 47. (a) The interest on a man’s investment increases from 8 % to 11 % per annum. 4 4 Find the value of his investment if his annual income from it increases by $75. (b) The cost of manufacturing a car is $7 800. Find the selling price of the car if it is 1 [5] sold at a profit of 17 % on the cost price. 2 48. A man buys a flat for $100 000 and rents it out. He puts 14% of each month’s rent aside for repairs and maintenance of the flat; pays $272 in taxes per year and realises 1 8 % on his investments. Calculate the monthly rent, correct to the nearest dollar. 2 [3]

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1.

(a) $40 (b) 18kg

2.

$578.20

3.

(a) 99 275 (b) 79%

4.

(a) $315 (b) $300 (c) 5%

5.

12

6.

(a) 106 (b) 27.2%

7.

(a) $5 760 (b) $4 800, 16.7% (c) $10 800

8.

(a) 35.2 cm (b) 1.254 km

9.

(a) $4 640 (b) 14¼ % (c) $7 104 (d) $5 000

10.

$1 485

11.

$288

12.

6% decrease

13.

$187.88

14.

$4.80

Teachers’ Resource NSM 3

© Oxford University Press

15.

$75.31

16.

(a) 30 (b) $2 629.90 (c) $630.90

17.

(a) $14 280 (b) $52 250

18.

(a) $75 (b) $2 535

19.

(a) $14 # 750, $23 095 (b) $37 845 (c) $9 461.25

20.

$1 600, 8.75%

21.

7:2

22.

$240

23.

$1.26

24.

$450

25.

$41 268

26.

$25 000

27.

20%

28.

8 : 11

Teachers’ Resource NSM 3

© Oxford University Press

29.

5:3

30.

50

31.

40 km/h

32.

$984.10

33.

$76.61

34.

(a) 78 km/h (b) 13 42

35.

$540, $216

36.

606 kg

37.

2:1

38.

8%, 25.9%

39.

$1 617

40. (a) $12 540

(b) 1682 Malaysian ringgits

41. (a) $13.20

(b) $1 090

42. (a) $15 000

(b) $21 750

43. (a) $3 800

(b) $29 200

44. (a) $1 820

(b) 6%

45. (a) $2 640

(b) $42 000

46. 650 light bulbs, $1.20 Teachers’ Resource NSM 3

© Oxford University Press

47. (a) $3 000

(b) $9 165

48. $850

Teachers’ Resource NSM 3

© Oxford University Press

Chapter 7

Secondary 3 Mathematics Chapter 7 Linear Graphs and Their Applications ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 173) Suppose 32 rabbit heads were counted . The number of legs would have been 32 × 4 = 128. This is 128 – 100 = 28 legs more than those counted. We can assume that these extra legs belong to the chickens and therefore, there are 28 ÷ 2 = 14 fewer rabbits. ∴ the number of chickens counted = 14 and the number of rabbits counted = 32 –14 = 18. Therefore, there are 14 chickens and 18 rabbits. Just For Fun (pg 176) Let x be the number of husbands who are taller than their wives, y be the number of husbands who are heavier than their wives and z be the number of husbands who are taller and heavier than their wives. (A Venn diagram clarifies the problem.) 2 3 Then z = x, z = y and 1 000- x - y + z = 120 giving x = 720. 3 4

Just For Fun (pg 183) Let the distance for the whole journey be d km and Chonglin's speed be x km/h. 3 15 d d d d Then we have − and − . Hence, the solution is d = 30. = = x x + 1 60 x x + 6 60

Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 7 Linear Graphs and Their Applications GENERAL NOTES As an introduction to the topic, the teacher may spend a little bit of time introducing and discussing the many situations that make use of the idea of co-ordinate geometry. Some of the examples not mentioned in the text are: (1) The latitude and longitude of a place on earth, i.e. map work. (2) The seating layout in cinemas, stadiums, etc. with which most students should be familiar. (3) The display of flashcards during the National Day celebrations. Each card bearer is given a row and a column number for the co-ordinator to supervise. (4) Before a mural is painted on a wall, a picture is normally drawn on a piece of grid paper and then transferred to the wall. Bring their attention also to the relationship between the graphs of y = x + c and y = x and in general to the relationship between the graphs of y = mx + c and y = mx, i.e. the graph of y = x + c is the translation of the graph of y = x, c units up or down parallel to the x– axis depending on whether c > 0 or c < 0 and the graph of y = mx + c is the translation of the graph of y = mx, c units up or down parallel to the x–axis depending on whether c > 0 or c < 0. Thus, lead students to the conclusion that the graphs of y = mx + c for various values of c are parallel and cut the y–axis at different points corresponding to different values of c. Emphasise the fact that when two quantities are related in any way, it is often useful to show the relationship by means of a graph and the purpose of a graph is to convey information visually and quickly. Stress also that a good graph must be neat, clear and concise. Conversion graphs are something new to the students for at primary level, they were exposed only to travel graphs. A conversion graph is also known as a “ready reckoner”. A “ready reckoner” relating the cost of a copper pipe to its length may be found on a chart of a building material supplier. Using this graph, a salesman can quickly determine the cost of any length of copper piping. Besides the type of conversion graphs discussed in the textbook, teachers may like to get students to suggest other types of everyday situations where conversion graphs may be useful. The Dynamic Mathematics Series on “The Business of GRAPHS” will provide extra drill and practice for the pupils if your school do have these CDs. Choice of scale is important in this chapter. A scale will be determined by the biggest and lowest values of a given variable. The scale should be as large as possible as this allows space for more details. Plotting or graphing should be done carefully and neatly. The scale and names of the quantities (along the respective axes) should be clearly specified. Students must also be reminded of the following precautions when reading off figures from any graph: • Check the scale • Check the starting point of the respective axes • Use a ruler Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ ( Class: _______

)

Date: ____________ Time allowed: min Marks:

Secondary 3 Mathematics Test Chapter 7 Linear Graphs and Their Applications

1. The diagram shows the different lengths of a spring when different weights are attached to it. (a) What is the original length of the spring? (b) What is the length of the spring when the attached weight is 12 g? (c) Find the attached weight if the spring is extended by 2.4 cm from its original length.

[1] [1] [1]

2. The graph shows the different weights of an object on Earth and on the Moon. Use the graph to find the weight of an object (a) on Earth if it weighs 14 kg on the Moon, (b) on the Moon if its weight on earth is 48 kg.

[1] [1]

Teachers’ Resource NSM 3

© Oxford University Press

3. The graph shows the cost in dollars of printing various numbers of name cards. From the graph, find (a) the cost of printing (i) 100 cards (ii) 150 cards (iii) 300 cards (b) the number of cards that could be printed for (i) $100 (ii) $250 (iii) $300

[1] [1] [1]

[1] [1] [1]

4. The table below displays the distance travelled by a car and the amount of petrol remaining in the tank.

(a) Draw a graph to show the relationship between the distance covered and the amount of petrol in the tank, using suitable scales. [2] (b) When the car has travelled 50 km, how much petrol is left in the tank? [1] (c) The car starts with a full tank of 50 litres. How far has the car travelled before the tank is empty? [1] (d) If the car travels at an uniform speed throughout, what is the rate of consumption of petrol? [2] (e) How far has the car travelled when only 21 litres of petrol remain in the tank? [1]

5. It is given that 1 kg of soya beans is required to produce 6 litres of soya bean milk. If x denotes the weight of soya beans needed and y the amount of soya bean milk produced, draw a graph to illustrate the relationship between x and y. [2] Use your graph to find (a) the amount of soya bean milk produced by (i) 4 kg of soya beans (ii) 6.5 kg of soya beans [2] (b) the weight of soya beans needed to produce (i) 12 litres of soya bean milk (ii) 21 litres of soya bean milk

Teachers’ Resource NSM 3

[2]

© Oxford University Press

6. The distance-time graph shows the graph of Joshua's journey when he goes to visit his teacher. (a) How far away does his teacher live? [1] (b) What is the fastest speed at which he travelled? [1] (c) How long did he rest altogether? [1]

7. It is given that US$10 was equivalent to S$15 in July 1997. Draw a graph to show the relationship between American and Singapore dollars up to US$100. Use your graph to find the conversion of the following: (a) American dollars into Singapore dollars (i) US$16 (ii) US$72 [2] (b) Singapore dollars into American dollars (i) S$30 (ii) S$96 [2]

8. The diagram shows the distance-time graph of a motorist after leaving home. Using the graph, find (a) the speed in km/h, during the last 30 minutes. [2] (b) the average speed, in km/h, for the whole journey. [2]

Teachers’ Resource NSM 3

© Oxford University Press

9. A restaurant owner pays a waiter an amount of $A per day. The amount is made up of a fixed daily wage plus a variable amount, which depends on the number of customers he serves. The graph illustrates the relationship between $A and n, which is the number of customers he serves. Use the graph to find (a) the fixed daily wage [1] (b) the amount of money he received in a day when he served 50 customers [1] (c) the number of customers he served on the day he received $46 [1]

10. The maximum number of marks in an examination is 60. The table below shows the relationship between the actual marks obtained by some candidates and their percentage marks.

Using suitable scales, draw a graph to convert the actual marks to percentage marks. From your graph, find (a) the percentage marks obtained by a candidate with (i) 15 marks (ii) 48 marks (b) the actual marks of a candidate whose percentage marks are (i) 35 (ii) 55

Teachers’ Resource NSM 3

[1] [1]

© Oxford University Press

11. The graph shows the change in the temperature of the water in a hot water tank after the heater is switched on. Use your graph to find (a) the temperature of the water in the tank after (i) 28 minutes (ii) 1 hour 24 minutes [2] (b) the time taken for the temperature to reach (i) 32° C (ii) 76° C

[2]

12. The diagram shows the distance-time graph of Mr Chew. (a) How far did he travel? (b) What is his speed for the first hour? (c) Find his average speed for the whole journey.

[1] [1] [2]

13. The diagram shows the travel graph of a moving body after leaving a starting point. Using the graph, find (a) the time interval during which the body is stationary, (b) the speed during the last minute, (c) the average speed for the whole journey in km/h.

[1] [2] [3]

Teachers’ Resource NSM 3

© Oxford University Press

14. The diagram shows the travel graph of a car. Using the graph, find (a) the speed of the car for the first part of the journey, (b) the duration during which the car stopped, (c) the average speed of the car for the whole journey, (d) the fastest speed of the car during the journey.

[1] [1] [2] [1]

15. Given that 36 km/h is equal to 10 m/s, construct a graph for converting km/h to m/s. Use your graph to convert (a) 55 km/h to m/s, (b) 108 m/s to km/h.

[3] [1] [1]

16. Given that 5 kg =11 pounds, construct a graph for converting pounds to kg and vice versa. Use your graph to convert align (a) 66 pounds to kg, (b) 45 kg to pounds.

[3] [1] [1]

17. The diagram shows the distance-time graph of a motorist. (a) How far did he travel in the first hour? (b) What was his average speed during the first hour? (c) What is his speed during the last leg of his journey? (d) What is his average speed for the whole journey?

[1] [1] [1] [1]

Teachers’ Resource NSM 3

© Oxford University Press

18. The graph shows the journey of Peter who leaves home at 5 p.m. (a) What is Peter's average speed for the outward journey? (b) How many hours was Peter away from home? (c) How far did Peter travel in total? (d) What is Peter's average speed for the entire journey?

[1] [1] [1] [1]

19. The graph shows the cost ($C) of hiring a van to travel D km from a rental company. Use the graph to find (a) the cost of hiring a van to travel (i) 34 km, [1] (ii) 68 km. [1] (b) the distance travelled if the cost of hiring a van is (i) $52 [1] (ii) $32 [1]

20. Given that 10 gallons = 45 litres, construct a graph to convert gallons to litres and vice versa. Use your graph to (a) convert into litres (i) 4 gallons (ii) 6 gallons (b) convert into gallons (i) 21.6 litres (ii) 39.6 gallons [4]

21. It is given that S$1 was equivalent to 20 Thai baht in July 1997. Draw a graph to show the relationship between the Singapore dollar and the Thai baht up to 200 Thai baht. Use your graph to find the conversion of the following: (a) Singapore dollars into Thai baht (i) $5.50 (ii) $8.20 (b) Thai baht into Singapore dollars (i) 140 baht (ii) 88 baht

Teachers’ Resource NSM 3

[2]

[2] [2]

© Oxford University Press

22. It is given that S$55 was equivalent to M$100 in July 1997. Draw a graph to show the relationship between the Singapore dollar and the Malaysian ringgit up to M$100. Use your graph to convert (a) into Malaysian ringgit (i) S$22 (ii) #S$45 [2] (b) into Singapore dollars (i) M$60 (ii) M$82 [2]

23. It is given that HK$10 was equivalent to ¥160 in July 1997. Draw a graph to show the relationship between Hong Kong dollars and Japanese yen up to ¥800. Use your graph to convert into (a) Japanese yen (i) HK$25 (ii) HK$42 (c) Hong Kong dollars (i) ¥480 (ii) ¥640 [4]

24. The graph shows the rate at which the water is emptied from a container. Use the graph to find (a) the amount of water in the container at first, (b) the time taken to empty the container, (c) the volume of water in the container after 3 seconds, 3 (d) the time taken to empty of the tank. 4

Teachers’ Resource NSM 3

[1] [1] [1] [1]

© Oxford University Press

25. The diagram shows the travel graphs of Peter and Paul. From the graphs, find (a) Peter's speed in the first two hours, (b) the distance between them at 12 noon, (c) Paul's speed throughout the journey, (d) the difference between their average speeds for the entire journey.

[1] [1] [1] [2]

26. It is given that A$75 was equivalent to 100 German marks (DM) in July 1997. Draw a graph to show the relationship between the Australian dollars and German marks up to DM100. Use your graph to convert (a) into German marks (i) A$39 (ii)A$63 (b) into Australian dollars (i) DM60 (ii) DM80 [4]

27. The diagram shows the travel graph of a moving body. (a) What section would indicate that the body was resting? (b) Which section shows the body moving at the fastest speed? (c) Find the average speed in km/h of the body for the entire journey.

Teachers’ Resource NSM 3

[1] [2] [1]

© Oxford University Press

28. The diagram shows the relationship between the expenses of a basketball tournament and the number of players attending the tournament. From your graph, find (a) the expenses when the number of players is (i) 12 (ii) 48 (b) the difference in the number of players when the expenses differ by 100 dollars.

[2] [1]

29. It is given that S$24 was equivalent to 100 French francs in July 1997. Draw a graph to show the relationship between the Singapore dollars and the French franc for up to 100 francs. Use your graph to find the conversion of the following: (a) Singapore dollars into French francs (i) S$8 (ii) S$18 (b) French francs into Singapore dollars (i) 25 francs (ii) 80 francs [4]

30. Given that 10 m/s is equivalent to 36 km/h, draw a conversion graph using the following scales: Horizontal: km/h, 0 to 150, 1 cm to 10 km/h Vertical: m/s, 0 to 40, 2 cm to 10 m/s Use your graph to change to (a) m/s (i) 72 km/h (ii) 126 km/h (b) km/h (i) 15 m/s (ii) 40 m/s

Teachers’ Resource NSM 3

[4]

© Oxford University Press

31.

The diagram above shows the graph for converting gallons to litres. (a) A motorist bought 5.2 gallons of petrol. Given that 1 litre of petrol costs $1.50, use the conversion graph to calculate how much the motorist paid for petrol. (b) Given that 1 gallon of milk costs $11.25, use the graph to calculate the cost of 18 litres of milk. [4] 32. Given that 20 m/s is equivalent to 72 km/h, draw a conversion graph using the following scales: Horizontal: km/h, 0 to 100, 1 cm to 10 km/h Vertical: m/s, 0 to 30, 2 cm to 10 m/s Use your graph to change to (a) m/s (i) 36 km/h (ii) 55 km/h (iii) 75 km/h (b) km/h (i) 5 m/s (ii) 25m/s (iii) 14m/s [8] 33. Draw a conversion graph to convert marks out of 65 to percentage marks using suitable scales. Use your graph to convert the following marks out of 65 to percentage marks: (a) 6 (b) 26 (c) 39 (d) 54 (e) 63 [8] 34. On a certain day in 2006, the exchange rate for US$80 was S$130. Draw a graph to convert American dollars to Singapore dollars. Use your graph to (a) change to Singapore dollars (i) US$30 (ii) US$48 (iii) US$69 (iv) US$150 (b) change to American dollars (i) S$21 (ii) S$85 (iii) S$112 (iv) S$270 [10]

Teachers’ Resource NSM 3

© Oxford University Press

35. In an experiment, a rat was placed at different distance d (in cm) from a goal box and the pull p (in g) of the rat towards the food placed in the goal box was measured. 1 The formula connecting p and d is p = − d + 70, 30 ≤ d ≤ 175 . 5 1 (a) Draw the graph of the equation p = − d + 70, 30 ≤ d ≤ 175 . 5 (b) Use your graph to find the value of p when the value of d is (i) 35 (ii) 66 (iii) 125 (iv) 160 [7]

36. The formula connecting the cost, $ C, in producing n television sets is C = 96 000 + 80n. (a) Draw the graph of this equation for 0 ≤ n ≤ 1000 . (b) Use your graph to find the cost for producing (i) 50 (ii) 125 (iii) 650 (iv) 800 television sets. (c) Given that m television sets cost $132 000 to produce, use your graph to find the value of m. [7] 37. Train 1 travels from Town P to Town Q, a distance of 500 km apart. It leaves Town P at 07 00 and arrives at Town Q at 13 00. Train 2 leaves Town Q at 07 00, arriving at Town P at 14 00. The diagram below shows the distance-time graphs of the two trains. Find (a) the distance travelled in the first two hours by each train, (b) the speed of each train before the first stop, (c) when and where the two trains passed each other, (d) the average speed of each train for the entire journey. [6]

Teachers’ Resource NSM 3

© Oxford University Press

38.

Harry leaves Town A at 06 00 to travel to Town B, 60 km away. Two hours later, Steven leaves Town A to travel to Town B too. The graph above shows the distance they had travelled in a given time. Find (a) how long Steven took to reach Town B and his speed for the journey, (b) when and where Steven overtook Harry, (c) how far Harry had travelled after 1 hour, (d) how far Harry had travelled when Steven reached his destination, (e) how long Steven took to travel 45 km, (f) Harry's average speed for the whole journey. [8]

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1.

(a) 2cm (b) 3.2 cm (c) 24g

2.

(a) 70kg (b) 9.5kg

3.

(a) (i) $150 (b) (i) 50 cards

(ii) $200 (ii) 200 cards

(iii) $350 (iii) 250 cards

4.

(b) 45 litres

(c) 500 km

(d) 0.1 litre per km

5.

(a) (i) 24 litres (b) (i) 2 kg

(ii) 39 litres (ii) 3.5 kg

6.

(a) 30 km

(b) 20 km/h

7.

(a) (i) S$24 (b) (i) US$20

(ii) S$108 (ii) US$64

8.

(a) 80 km/h (b) 51 3/7 km/h

9.

(a) $30

(b) $66

10.

(a) (i) 25 (b) (i) 21

(ii) 80 (ii) 33

11.

(a) (i) 28 °C (b) (i) 36 minutes

12.

(a) 60 km

(b) 24 km/h

(c) 15 km/h

13.

(a) 20 seconds

(b) 2.5 m/s

(c) 9 km/h

14.

(a) 93 1/3 km/h

(b) ½ hour

(c) 70 km/h

(d) 120 km/h

15.

(a) 198 m/s

(b) 30 km/h

16.

(a) 30 kg

(b) 99 pounds

17.

(a) 40 km

(b) 40 km/h

(c) 120 km/h

(d) 50 km/h

18.

(a) 13 1/3

(b) 4 hours

(c) 80 km

(d) 20 km/h

(e) 290 km

(c) 1 hour

(c) 22 customers

(ii) 60 °C (ii) 112 minutes

Teachers’ Resource NSM 3

© Oxford University Press

19.

(a) (i) $40 (b) (i) 54 km

20.

(a) (i) 18 litres (b) (i) 4.8 gallons

(b) 27 litres (b) 8.8 gallons

21.

(a) (i) 110 baht (b) (i) S$7

(b) 164 baht (b) S$4.40

22.

(a) (i) M$40 (b) (i) S$33

(ii) M$82 (ii) S$45

23.

(a) (I) ¥ 400 (b) (i) HK$ 30

(ii) ¥ 672 (ii) HK$ 40

24.

(a) 80 litres

(b) 10 seconds

(c) 56 litres

(d) 7.6 seconds

25.

(a) 75 km/h

(b) 50 km

(c) 75 km/h

(d) 25 km/h

26.

(a) (i) DM 52

(ii) DM 84

(b)(i) A$45

(ii) A$60

27.

(a) BC

(b) CD

28.

(a) (i) $560 (b) 20

(b) $740

29.

(a) (i) 33 francs (ii) 75 francs (b) (i) S$6 (ii) S$ 19

30.

(a) (i) 20 m/s (b) (i) 54 km/h

31. (a) $36

(ii) $60 (ii) 20 km

(ii) 35 m/s (ii) 144 km/h

(b) $45

32. (a) (i) 10 (b) (i) 18 33. (a) 9

(d) 3 3/7 km/h

(b) 40

34. (a) (i) 49 (b) (i) 13 35. (b) (i) 63

(ii) 15

(iii) 21

(ii) 90

(iii) 50

(c) 60

(d) 83

(e) 97

(ii) 78

(iii) 112

(iv) 244

(ii) 52

(iii) 69

(iv) 166

(ii) 57

(iii) 45

(iv) 38

36. (b) (i) 100 000 Teachers’ Resource NSM 3

(ii) 106 000 (iii) 148 000 (iv) 160000 © Oxford University Press

(c) 450 37. (a) 100 km, 150 km (c) 10 18, 270 km from Town P 38. (a) 1 hour 30 min, 40 km/h (d) 35 km

Teachers’ Resource NSM 3

(b) 80 km/h, 100 km/h 1

3

3

7

(d) 83 km / h , 71 km / h (b) 08 42, 27 km from Town A

(c) 10 km

(e) 1 hour 6 min

(f) 10 km/h

© Oxford University Press

Chapter 8

Secondary 3 Mathematics Chapter 8 Congruent & Similar Triangles ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 206) The 6 toothpicks can be joined to form a tetrahedron, thus giving 4 congruent triangles. This is an example to let students view a problem from other non-conventional methods, switching from 2-dimensional to 3-dimensional solutions. Just For Fun (pg 216)

Just For Fun (pg 219) 1.

Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 8 Congruent & Similar Triangles GENERAL NOTES In this chapter some simple applications of congruent triangles and similar triangles are discussed. (Teachers may ask their students to come up with some other applications.) Many students enjoy field activities in mathematics. They can also try using the methods mentioned in Questions 10 and 11 (pg 233) to determine the height of a tree on school grounds. The puzzles and exploration at the beginning of the chapter will help students to grasp the concept of congruency. It may be useful here to repeat the way the concept of congruency is used in everyday situations such as in the replacement of worn-out parts with the same part number etc. In discussing the tests for similarity between two triangles, lead up to the idea that two triangles are similar if they can be made congruent by enlargement or reduction. The geoboard ( shown below) can serve as an excellent aid in illustrating this idea. It can also be used to illustrate congruency tests. For example, teachers can ask their students to form another triangle having sides equal to the three sides of the triangle shown on the right. This can be repeated by having them form a triangle so that the triangle formed and the given triangle have two sides and included angle equal and so on. In each case, students should note whether the triangle formed and the given triangle are congruent.

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: 35 min Marks:

Class: _______

9 Secondary 3 Multiple-Choice Questions Chapter 8 Congruent & Similar Triangles

1. In the diagram, PQ is parallel to BC, AP = PB and QC = CR. Given that BC = 8 cm, the length of SC in cm is (A) 4

(B) 2

(C) 2

2 3

(D) 6 (E) 5

2. In the diagram, PQ = 4 cm, QR= 2 cm, OQ = 6 cm and QS = 3 cm. We say that (A) triangles RSQ and POQ are similar. (B) triangles SOP and PQO are similar. (C) RP and SO intersect at right angles. (D) triangles SQP and RQO are congruent. (E) O, P, R and S are points on the circumference of a circle.

Teachers’ Resource NSM 3

1 3

(

)

(

)

© Oxford University Press

3. In the diagram, ∠XMY = ∠XNZ = 90°. If XY = XZ, then (A) ∆XYZ is equilateral. (B) Triangles XMY and XNZ are congruent. (C) Triangles XNZ and YMZ are similar. (D) ∠XYZ = 90°. (E) YZ = YM = ZN. (

)

4. In the diagram, ∠ABC = ∠BDC = 90°, BC = 5 cm and DC = 3 cm. The length of AD in cm is (A) 8

1 3

(B) 5

Teachers’ Resource NSM 3

(C) 5

1 3

(D) 2

(E) 12

(

)

© Oxford University Press

5. In the diagram, ABˆC = ACˆE = CDˆE = 90°, AB = 6 cm, BD = 14 cm and DE = 8 cm. Calculate BC. (A) 6cm only (B) 7cm only (C) 8cm only (D) 9cm only (E) 6cm or 8cm ( )

6. In the diagram, PQ // BC. If PR = 6 cm and RC = PB = 14 cm, then AP is 2

(A) 6cm (D) 10

1 2

(B) 32 cm 3

cm

(C) 14cm

(E) 20cm

(

)

(

)

7. In the diagram MN//XY, MN = 25 cm, MO = 20 cm and YO = 70 cm. What is the length of XY? (A) 87 cm (D) 88

1 2

cm

1

(B) 87 cm 2 1

(C) 88 cm

(E) 89 cm

Teachers’ Resource NSM 3

2

© Oxford University Press

8. Which of the following cases represent a pair of congruent triangles? (A) I only (B) II only (C) III only (D) I and II only (E) I and III only

(

)

$ = TSQ $ , PQR $ = TQS $ = 90° , PR = 8 cm and PQ = ST = 6 cm. Find the 9. In the diagram PRQ length of QT.

(A) 3cm

1

(B) 4 cm 2

(C) 6 cm

(D) 8 cm

(E)

2 9

cm (

Teachers’ Resource NSM 3

)

© Oxford University Press

Answers 1. B 6. D

2, A 7. B

Teachers’ Resource NSM 3

3. B 8. E

4. C 9. B

5. A

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: min Marks:

Secondary 3 Mathematics Test Chapter 8 Congruent & Similar Triangles 1. Copy and complete the following: In ∆ PQR and ∆ TSR, PQ = ________

$ ________ = TSR QR = ________

∴ ∆ PQR

≡ ∆ TSR ( ________ )

∴ PR = ________ $ = ________ . and QPR [3]

2. Copy and complete the following: In ∆ ABC and ∆ ADC , AB = ________ $ = ________ BAC AC = ________ ∆ ABC = ∆ ADC ( ________ ) BC = ________ $ = ________ and ACB [3]

3. Given that ∆ A a = ________ b = ________ x = ________ y = ________ z = ________

≡ ∆ B, copy and complete the following:

[3]

Teachers’ Resource NSM 3

© Oxford University Press

4. Given that ∆ A a = ________ b = ________ x = ________ y = ________

≡ ∆ B, copy and complete the following:

[2]

5. Copy and complete the following: In ∆ ABC and ∆ BAD,

$ = ________ ACB $ BAC = ________ AB = ________ ∴ ∆ ABC ≡ ∆ BAD ( ________ ) ∴ AC = ________ and BC = ________ .

[3]

6. In the diagram, ABCD is a rectangle and AE // FC. Copy and complete the following: In ∆ ADE and ∆ CBF,

$ = ________ ADE $ DAE = ________ AD = ________ ∆ ADE ≡ ∆ CBF ( ________ ) DE = ________ and AE = ________ . [3]

7. In the figure, ∆ PQR and ∆ PMN are similar. Find the values of x and y.

Teachers’ Resource NSM 3

[4]

© Oxford University Press

8. In the diagram, AB is parallel to PR. Given that QB = 4 cm, 2

BR = 6 cm, PR = 15 cm and the area of ∆ PBR = 9a cm , find

(a) the length of AB [2] [2]

(b) the area of ∆ PQR in terms of a.

9. In the diagram, M is the mid-point of AC, AMB =DMC and MB=DM. Name a pair of congruent triangles and state the case for congruency. [2]

10. In the diagram, AD // MC, MD // BC and M is the mid–point of AB. Prove that ∆ AMD copy and complete the following:

≡ ∆ MBC by

$ = ________ DAM $ = ________ AMD AM = ________ ∆ AMD = ∆ MBC ( ________ )

11. In the diagram, AP ⊥ BP, BQ ⊥ AQ and AP = AQ. Prove that ∆ ABP the following: $ = ________ = ________ APB AP = ________ AB = ________

∆ ABP

[4]

≡ ∆ ABQ by copy and complete

≡ ∆ ABQ ( ________ )

[4]

12. In the diagram, given that ∆ PRS and ∆ QRT are similar, find the length of TR.

Teachers’ Resource NSM 3

[2]

© Oxford University Press

13. In the diagram shown, PQ // BC. Calculate the values of x and y.

[4]

14. In the diagram, the radii of the two circles touching each other are 5 cm and 3 cm respectively. Calculate the length of BC. [3]

15. In the diagram, all lengths are given in cm. Find the length of the side marked with the letter x. [4]

16. In the diagram, DE // AC. Find (a) the lengths of the sides marked with x and y. (b) the ratio of the parameters of ∆ ABC and ∆ DBE.

[3] [2]

17. At 10 00, a boy and a tree cast shadows of lengths 2.5 m and 15 m respectively. If the boy’s height is 150 cm, find the height of the tree. [3]

Teachers’ Resource NSM 3

© Oxford University Press

18. The diagram below shows a girl ( PQ ), 120 cm tall, standing at a distance from a 4.8m-tall pole ( AB ).If the shadow of the girl on the ground is 1.5 m, find the distance BQ of the girl from the pole. [3]

19. The diagram shows a building AB, an electrical pole CD and a tree EF in a row. The tree, 5 m away from the building, is 6 m tall and casts a shadow of 8 m. Find (a) the height of the building AB, [3] (b) the distance FD of the pole from the tree if the pole is 9 m tall. [3]

20. The diagram shows a ladder, 5 m long, reaching the top of a building from level ground. A worker 4 has moved up of the ladder such that his horizontal distance from the building is 40 cm. Find the 5 distance QR of the foot of the ladder from the foot of the building. [3]

Teachers’ Resource NSM 3

© Oxford University Press

21.

Give a reason why the pair of triangles in (a) are not similar and in (b) are similar.

$ = PQR $ , STP $ = QPR $ . If PT = 6 cm, QR = 14 cm and PS = 6 cm, 22. In the diagram SPT find the length of QT.

[2]

[2]

23. In the diagram, TS // NP and SR // PQ. If MR = 5 cm, RQ = 3 cm, MS = 6 cm and MN = 12 cm, find the length of MT. [3]

24. In the diagram, PW = WU = US = SQ and PX = XV = VT = TR. If QR = 8 cm, ST = a cm, UV = b cm and WX = c cm, find the value of a + b + c.

Teachers’ Resource NSM 3

[4]

© Oxford University Press

25. The diagram shows a flagpole ST, 10 m tall and a building PQ, 30 m tall. Alvin stands between $ = RPQ $ . Find his distance from the flagpole. the pole and the building at the point R such that RST [3]

26. The diagram shows two similar triangles. Calculate the value of l 1 + l 2 .

[3]

$ = LMN $ = 90 . 27. In the diagram, ON = NM, PN = LM and ONP (a) Prove that ∆ OPN = ∆ NLM. $ = 32° , find OPN $ . (b) If LMN

[3] [1]

28. In the diagram, DF ⊥ BC, DG ⊥ AB, DE ⊥ AE, BC ⊥ AE, DG = DE and BF = CF. (a) Name two pairs of congruent triangles and state the property for congruency in each case. [2] (b) If HC = 4 cm, DE = 7.2 cm and CE = 4 cm, calculate the length of AE. [3]

Teachers’ Resource NSM 3

© Oxford University Press

29. In the diagram, ABC is a right-angled triangle and LNBM is a square. If BC = 12 cm and 1 AB = 7 cm, find the area of the square LNBM. 5

[4]

30. In the diagram, DE // GH // BC and DE : GH : BC = 5:7:10. (a) If FH = 21 cm, find the length of DF. (b) If GB = 12 cm, find the length of FG.

[1] [2]

31. In the diagram, PQRS is a parallelogram and ABCD is a straight line. Given that AQ = 3 cm, 1 QP = 7 cm, PC = 6 cm and BR = 5 cm, calculate 2 the length of (a) QB (b) CS (c) SD

[2] [1] [3]

Teachers’ Resource NSM 3

© Oxford University Press

32. In the diagram, OR // PQ // ST. Given that OP = x units, PS = 2.5x units, OR = 4y units and OQ = x + 2y units, express (a) PQ in terms of y, (b) ST in terms of y, (c) express QT in terms of x and y.

[2] [2] [2]

$ . Find the value of the ratio x : y. $ = CDE 33. In the diagram, ABC

[3]

34. In the diagram, PR // BC, PQ // BR, AP = 8 units, PB = x units, PR = 12 units, BC = 16 units, AR = 6 units and QR = y units. Calculate the value of the product xy. [6]

35. In the diagram, AB // PQ, AC // PR, BQ = x units, QS = 4 units, SR = 5 units and RC = 6 units. Find the value of x. [4]

Teachers’ Resource NSM 3

© Oxford University Press

36. In the diagram, AB // CD // PQ, AC = 6 units, CP = 12 units, AX = 16 units, XQ = x units, BD = 7 units and DQ = y units. Find the value of x + y.

[6]

37. In the diagram PQ // BC, QR // AD, AP = 10 cm, PB = 3 cm, QC = 4 cm, AR = x cm and AD = 12 cm. Calculate the value of x.

[5]

38. In the diagram, PQ // BC, QR // AD, AP = 10 cm, PB = 5 cm, DR = x cm and RC = 4 cm. Find the value of x.

[5]

Teachers’ Resource NSM 3

© Oxford University Press

39. In ∆ ABC, PD =

4 5

PR and PA =

5 6

PQ. AR and DQ meets at B and AQ // DC.

1

PQ, 6 (b) ∆ ABQ and ∆ DBC are congruent.

Prove that (a) DC =

[2] [3]

40. In the diagram, AC // QR. PQ = PR = 28 cm, AC = PC = 20 cm and QR = 14 cm. (a) Prove that ∆ PQR and ∆ ACP are similar. (b) Calculate the length of AQ.

[2] [3]

41. In the diagram, PQR is a triangle, right–angled at P. PS is the perpendicular from P to QR. (a) Prove that ∆ RSP and ∆ PSQ are similar. (b) Given that QS = 36 cm and RS = 25 cm, find the length of PS.

[3] [2]

Teachers’ Resource NSM 3

© Oxford University Press

42. The sides of a triangle are 9 cm, 7 cm and 6 cm long. The longest side of a similar triangle is 6 cm. Find the lengths of the other sides of the second triangle. [3]

43. In the diagram, SR is parallel to PQ. SP = 3 cm, TS = x cm, TR = y cm and RQ = 4cm. Write down an equation connecting x and y. Given that PQ = 2SR, write down the values of x and y. [5]

44. A cone has a height of 12 m and a base radius of 5 m. Find the diameter of the circular section cut out from the cone by a plane parallel to the base and 3 m away from it. [3] 45. ∆ABC is right-angled at A. Given that AD is perpendicular to BC, prove that [4] AB ×AD=BD ×AC.

46. In the diagram, ABCD is a parallelogram and EDA and EFGB are straight lines. If EF = 10 cm and FG = 8 cm, calculate the length of GB. [4]

47. In the diagram, AB // QR, BC // PS, PA = 3 cm, AQ = 1 cm and BC = CS = 2cm. Calculate the length of (a) PS, (b) RC.

Teachers’ Resource NSM 3

[4]

© Oxford University Press

48. In the diagram, DF is parallel to BC, EF is parallel to DC, BC = 6 cm, DE = 2.4 cm, CF = 2 cm and AF = 8 cm. Calculate the length of (a) AE, (b) DB, (c) DF. [6]





49. In the diagram, A C B = A P Q , AP = 5cm, PQ = 4 cm and BC = 6 cm. Calculate the length of AC. [3]

50. In the diagram , PA // NM // BC, M is the mid-point of AC, PA = 5 cm and PC = 4PQ. Find the length of MN. [4]

51. In the diagram, PR // YZ, PR = 6 cm, RS = 3 cm and SQ = 7 cm. (a) Calculate the length of SY. (b) If XZ = 5RZ, find the length of YZ. [5]

52. Find the value of x in the diagram. [4]

Teachers’ Resource NSM 3

© Oxford University Press

53. Find the value of y in the diagram. [4]

54. In the diagram, XY is parallel to PQ. OP = OQ = 24 cm, XY = OY = 16 cm and PQ = 9 cm. (a) Prove that triangles OPQ and YXO are similar. (b) Calculate the length of XP. [5] ∧



55. In the diagram P Q R = P R Q , PM is perpendicular to QR and XY is perpendicular to PQ. Given that PQ = 13 cm, QR = 10 cm, PM = 12 cm 1

and XY = 2 cm, find the length of QY. 2

[4]

Teachers’ Resource NSM 3

© Oxford University Press

Answers $ $ , SR, SAS, TR, STR 1. TS, PQR $ , AC, SAS, DC, ACD $ 2. AD, DAC

3. a = 90, b = 40, x = 12, y = 9, z = 8

4. a = 40, b = 70, x = 2, y = 3

$ , AB, AAS, BD, AD $ , ABD 5. BDA 6. CBF, BCF, BC, AAS, BF, CF

7. x = 21, y = 2

8. (a) 6 cm

1 3 (b) 15a cm

2

≡ ∆ CMD, SAS

9. ∆ AMB

$ , MBC $ , MB, AAS 10. CMB

$ , 90°, AQ, AB, RHS 11. AQB 12. 11

1 cm 4

13. x = 4.2, y = 3.2 14. 4 cm 15. 1.6 cm 16. (a) x = 11.2, y = 4

(b) 7 : 5

17. 9 m 18. 4.5 m

19.

(a) 9

3 m 4

(b) 4 m

20. 2 m

Teachers’ Resource NSM 3

© Oxford University Press

21.

18 9

=

10 5

=2≠

25

8

12

12

=

12 18

=

10 15

=

2 3

22. 8 cm 23. 7.5 cm

24. 12 25. 5 m 26. 25 27. (b) 58°

28.

(a) ∆ BFD (b) 9 cm

29. 20

≡ ∆ CFD, SAS; ∆ AGD ≡ ∆ AED, RHS

1 2 cm 4

30.

(a) 15 cm

31.

(a) 2

32. (a)

1 cm 2

(b) 28 cm

(b) 2 cm

20 y units 7

(c) 4 cm

(b) 10y units

(c)

5 x + 5 y units 2

33. 5: 8

34. 4 35. 4.8 36. 46

37. 9.2 38. 8

40. (b) 18 cm 41. (b) 30 cm

2

42. 4 cm, 4 cm 3

43. 4x = 3y; x = 3, y = 4 Teachers’ Resource NSM 3

© Oxford University Press

44. 7

1

m

2

46. 12 cm 47. (a) 8 cm (b) 48. (a) 9.6 cm

2 3

cm

(b) 3 cm

3

(c) 9 cm 5

1

49. 7 cm 2

1

50. 7 cm 2

1

51. (a) 4 cm 5

52. 13

53. 9

1

(b) 7 cm 2

1 5

3 13

54. 18 cm 55. 7 cm

Teachers’ Resource NSM 3

© Oxford University Press

Chapter 9

Secondary 3 Mathematics Chapter 9 Area and Volume of Similar Figures and Solids ANSWERS FOR ENRICHMENT ACTIVITIES Just For Fun (pg 241)

Just For Fun (pg 241)

Just For Fun (pg 242) (π–2) : 2 Just For Fun (pg 244) The diagonal joining the ends of the rectangle consists of two fine lines with a small gap in between forming an area of one square unit. Teachers can ask students to construct the figures using graph paper to let the students find out the answer. Just For Fun (pg 251) The dwarfs will have 10 times our body surface area and thus will lose heat and water 10 times our normal rate. They will die easily due to dehydration and heat loss. The giants will be 1 000 times heavier than us but their surface area will only be 100 times larger . The ability of the legs to support their weights depends on the cross–sectional area of their legs. As the cross–sectional area of the legs will only be 100 times as large, they would not likely be able to support their heavier weights. Do you notice that fat people have difficulty standing up for long? Have you noticed how thick the legs of an elephant are?

Teachers’ Resource NSM 3

© Oxford University Press

Secondary 3 Mathematics Chapter 9 Area and Volume of Similar Figures and Solids GENERAL NOTES Very often a scale model of a building is made before the building is actually built. Some students may have visited places like mini-Siam in Bangkok, mini-China in Taiwan and so on during their vacations. They can discuss the models they saw in these places. In addition, they can bring some photographs of those places to show to the whole class. Teachers can also ask them if they know the scales used in making the models that they have seen. Teachers can draw students' attention to commercial products which come in a range of sizes such as mineral water, toothpaste, hair shampoo, etc. Teachers can also ask them whether they are aware of the fact that the bottles or containers for each product are similar (different sizes but the same shape). Students can also find out whether the price is proportional to the net volume of the product. Some students may possess toy cars which are miniature models of real cars. They can bring along some of them to classes especially those with inscriptions of the scales used in making the models. Using the scale factors available, teachers may want students to answer some hypothetical questions like: If the area of the windscreen of the model is x cm², what will be the area of the windscreen of the actual car? If the capacity of the petrol tank of a real car is y litres, what will be the capacity of the petrol tank of the model? Teachers may also want to relate the present topic to the scales and map problems. Teachers can help students recall that if a map is drawn to a scale of 1 : n, then the ratio of the area on the map to the corresponding area on the ground is 1 : n².

Teachers’ Resource NSM 3

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: 35 min Marks: 12

Secondary 3 Multiple-Choice Questions Chapter 9 Area and Volume of Similar Figures and Solids 1. In the diagram, ABCD is a parallelogram. $ = 90° and the Given that OC = 4 cm, OXD area of ∆BCD = 12cm 2 , the length of DX in cm is (A) 4 (B)12 (C) 8 (D) 3 (E) 48 (

)

(

)

(

)

2. In the diagram, PQRS is a parallelogram. Given that M and N are the mid–points of PQ and QR espectively, the value of

Area of the ∆QMN

(A) (C) (E)

is

Area of PQRS 1

1

4 1

6 1

8 1

(B) (D)

10

12

3. If the area of a face of a cube is increased by 44%, then its volume will be increased by (A) 44% (B) 173% (C) 73% (D) 199% (E) 299%

4. The tents that Peter and Paul made are similar in shape. If Peter uses 9 times the amount of canvas as Paul, find the ratio of the volume of Peter's tent to Paul's tent. (A) 1:27 (B) 1:3 (C) 3:1 (D) 9:1 (E)27:1 ( )

Teachers’ Resource NSM 3

© Oxford University Press

5. In the diagram, PQ is parallel to BC, QR is parallel to AB and BR : RC = a : b. Find the ratio of the area of ∆PQR to the area of ∆ABC. (A) a² : (a + b)² (B) ab : (a + b)² (C) ab : 2 (a + b)² (D) 2ab : (a + b)² (E) ab : (a² + b²) (

)

6. If a spherical balloon is inflated so that its diameter is tripled, then the volume is increased by a factor of (A) 3 (B) 9 (C) 15 (D) 21 (E)27 ( ) 7. If each edge of a cube is increased by 140%, the percentage increase in the surface area is (A) 176 (B) 276 (C) 276 (D) 476 (E)576 ( ) 8. In the diagram, ABCD is a parallelogram. If YZ =

1 2

AB, what fraction of the area of

ABCD is the area of ∆XYZ? (A) (C) (E)

1

1

(B)

2 1

3 1

(D)

4 1

5

6

(

)

(

)

(

)

9. In the diagram, PQRS is a trapezium in which SR is parallel to PQ. Given that SR = 5 cm, RQ = 7 cm, PQ = 12 cm and the area of ∆PQR is 21 cm², the area of ∆SQR is (A) 15 cm² (C) 12

1 4

cm²

(B) 8 (D)

3

4 2 50 5

cm² cm²

(E) 36 cm² 10. In the diagram, AB // CD // YZ. If XA = 2 cm, AC = 4 cm, CY = 6cm and the area of ∆XYZ is 54 cm², then the area of the shaded region is (A) 27 cm² (B) 18 cm² (C) 20

1 4

cm²

(D) 12 cm²

(E) 24 cm²

Teachers’ Resource NSM 3

© Oxford University Press

11. In the diagram, triangles ABC and PQR are similar, PQ = 6 cm and AB = 3cm. If the area of ∆PQR is 40 cm², the area of ∆ABC is (A) 80 cm² (B) 18 cm² (C) 8 cm² (D) 10 cm² (E) 20 cm² (

)

(

)

12. In the diagram, ABCD is a trapezium in which AB : CD = 2 : 5. If the area of ∆CDE is 75 cm², then the area of ABCD is (A) 100 cm² (B) 147 cm² (C) 195 cm² (D) 300 cm² (E) 317 cm²

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. D 7. D

2. C 8. C

Teachers’ Resource NSM 3

3. C 9. B

4. E 10. D

5. A 11. D

6. E 12. B

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Chapter 9

Secondary 3 Mathematics Test Area and Volume of Similar Figures and Solids

1. If a sphere of radius 1.5 cm weighs 135 g, find the weight in grams of a sphere with radius 2 cm. [3]

2. The lengths of the sides of three cubes are in the ratio 3:2:1. 2

(a) If the total surface area of the smallest cube is 22 cm , find the total surface area of the largest cube. 3

(b) If the volume of the largest sphere is 81 cm , find the volume of the second largest cube.

[2] [2]

3

3. A bottle of height 8 cm has a volume of 120 cm . Find the volume of a similar bottle of height 24 cm. [2]

4. John has two spheres. If the ratio of the radii of the two spheres is 2:3, find the ratio of their (a) surface areas, (b) volumes.

[2]

5. The ratio of the surface areas of two similar cones is 0.72:3.92. Find the ratio of their (a) base diameters, (b) volumes.

[3] 3

6. A model of a building is made to a scale of 1:300. The building has a volume of 5 400 m . Calculate the volume of the model in cubic metres, giving your answer in standard form. [3]

7. (a) A cylindrical tower is 200 m high, and its diameter is 20 m. Taking π = 3.14, find its volume. [2] (b) Peter is making a clay model of the tower with a height of 20 cm. Find the volume of the clay 3

needed in m .

[3]

8. A small bottle is geometrically similar to a large one and the heights of the two bottles are 15 cm and 45 cm respectively. Write down (a) the ratio of the volume of the smaller bottle to that of the larger bottle, (b) the capacity of the larger bottle in litres if the capacity of the smaller bottle is 500 ml. [3]

Teachers’ Resource NSM 3

© Oxford University Press

9. A small traffic marker is geometrically similar to a large one and the diameters of the two markers are 12 cm and 24 cm respectively. Write down (a) the ratio of the total surface area of the small marker to that of the large marker, 2

(b) the total surface area of the small marker if the total surface area of the large marker is 196 cm . [3] 2

2

10. The area of two quadrilaterals are 49 cm and 64 cm . Find the ratio of their corresponding sides if they are similar. [2]

11. In the diagram, PQ is parallel to BC. Given that AQ = 6 cm, AC = 15 cm 2

and the area of ∆ APQ = 16 cm , find

(a) the area of ∆ ABC, (b) the area of PBCQ, (c) the area of ∆ BCQ.

[2] [1] [3]

12. A statue was melted down and recast into smaller, similar figures one-tenth of the original height. Given that a small figure is 30 cm tall and weighs 1.8 kg, find (a) the height of the original statue, [1] (b) the weight of the original statue. [2]

13. The surface area of two containers are in the ratio 144#:# 25. If the bigger container has a height of 3

96 cm and a volume of 5 184 cm , calculate (a) the height of the smaller container, (b) the volume of the smaller container.

[2] [2]

14. In the diagram, PQ // ST, XY // RT. (a) Prove that ∆ PQR and ∆ SXY are similar. [3] (b) Find the length of PT given that QR = 4 cm, RX = 2 cm, XS = 8 cm and XY = 16 cm. [3] QR (c) Find the numerical value of (i) SR area of ∆PQR (ii) [2] area of ∆TSR (d) Given also that the area of ∆ PQR is 24 cm² , calculate the area of ∆ TSR.

Teachers’ Resource NSM 3

[1]

© Oxford University Press

15. A building is made up of a cylinder and a cone on its top. Given that TX = 5 m, XS = 12 m, TS = 13 m and PQ = 10 m, find, taking π = 3.14,2 (a) the total surface area of the building, (b) the volume of the building, (c) the total surface area and the volume of a model of the building given that the diameter of the model is 120 cm.

16.The model of a boat is 150 cm in length and the length of the actual boat is 18 m. (a) If it costs $2.50 to paint the model, what will it cost to paint the actual boat? (b) If the weight of the model is 3 kg, what is the weight of the actual boat if it is made of the same material?

[3] [3] [4]

[2] [2]

17. Two containers shown in the diagram are geometrically similar.

The height of the smaller container is 8 cm and the height of the larger container is 12 cm. (a) The top of the smaller container has a circumference of 54 cm. Find the circumference of the top of the smaller container. [2] (b) Find the ratio of the area of the base of the smaller container to that of the larger container. [1] (c) Both containers are filled with paint. The cost of the paint in the larger container is $40.50. Find the cost of the paint in the smaller container. [2]

18. The areas of the bases of the two similar glasses are in the ratio of 4#:#25. (a) Find the ratio of the circumferences of the tops of the glasses. (b) Given that the capacity of the larger glass is 625 ml, find the capacity of the smaller glass.

[1] [2]

19. Two similar cones are such that the ratio of the areas of their circular bases is 36#:#4. Find (a) the ratio of the diameters of the circular bases, (b) the ratio of the volumes of the cones.

Teachers’ Resource NSM 3

[2] [1]

© Oxford University Press

3

3

20. The volumes of two pyramids are 125 cm and 216 cm . Find the ratio of their corresponding heights if they are similar. [2]

21. In the diagram, TU // PQ, SQ = 3 cm, RQ = 9 cm, PU = 6 cm and US = 2 cm. Given that the area 2

of ∆ PRS is 32 cm and RT = 2.4 cm, calculate (a) the length of TU, (b) the area of ∆ PQR, (c) the area of trapezium RSUT.

[2] [2] [2]

22. The areas of the bases of two similar pyramids are in the ratio 9:25. (a) Find the ratio of the heights of the pyramids.

[1]

3

(b) Given that the volume of the larger pyramid is 275 cm , find the volume of the smaller pyramid.

[2]

23. Two similar spheres have diameters of 20 cm and 28 cm respectively. The larger sphere has a 3

volume of 1 715 cm . Calculate the volume of the smaller sphere.

[2]

24. The two containers shown are geometrically similar with respective heights of 8 cm and 10 cm.

(a) The diameter of the base of the smaller container is 2.4 cm. Calculate the diameter of the base of the larger container. (b) The containers are completely filled with flour. Given that the large container holds 1.25 kg, find the mass of the flour in the small container.

[2] [3]

25. ABC is a triangle in which XY // BC. 2

Given that 5AX = 2XB and the area of ∆ AXY = 16 cm , find the area of the quadrilateral XYCB.

Teachers’ Resource NSM 3

[4]

© Oxford University Press

26. The diagram shows a trapezium ABCD in which AB // DC. The area of trapezium ABCD is 2

21 cm , AB = 2.5 cm, CD = 4.5 cm and EF = 4 cm respectively. Given that EF // AB, find the area of ABFE. [4]

27. The diagram consists of a right-angled ∆ ABC. D is the mid-point of AB and F is the mid-point 2

of AD. Given that AG // DE // BC and the area of the triangle is 36 cm , find the area of the trapezium FGED.

28. A bucket with a height of 16 cm holds 4 had a height of 32 cm?

[4]

1 litres. How many litres would a similar bucket hold if it 2 [2]

3

29. A statue is made from 4 050 cm of metal. 3

(a) Given that the density of the metal is 4 g/cm , calculate the mass (in kg) of the statue.

[2]

3

(b) The statue is 57 cm high. An accurate scale model of the statue is made from 150 cm of metal. Calculate the height (in cm) of the model. [2]

30. A model of a boat is made on the scale factor of

1

. If it costs $1.60 to paint the hull of the model, 5 what will it cost to paint the hull of the boat using the same paint? [3]

31. A certain brand of tea is sold in two sizes, similarly packed in tins of similar shape. The heights of the tins are 12 cm and 18 cm and the prices are $7.20 and $21.00. How much can you save in the purchase of the larger tin? [4]

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32. A large ingot of metal is melted down and made into 125 small ingots all similar in shape to the original ingot. If the length of each small ingot is 5.2 cm, what was the length of the original ingot? [3]

33.The diagram shows two similar cuboids. (a) Find the volume of B if the volume of A is 128 cm³. (b) Find the ratio of the total surface area of A to that of B.

2

[2] [1]

2

34. Two solid spheres have surface areas of 6 cm and 54 cm respectively. The mass of the larger sphere is 81 kg. Find the mass of the smaller sphere. [3]

2

35. A container has a surface area of 2 000 cm and a capacity of 8.75 litres. Find the surface area of a similar container which has a capacity of 15.12 litres. [3]

2

36. Given that MN = 4 cm, QR = 6 cm and the area of MNRQ = 20 cm , find the area of ∆ PMN below. [3]

37. Two similar cylindrical containers have base radii of 9 cm and 12 cm respectively. If the capacity 3

of the smaller container is 297 cm , find the capacity of the larger container.

[3]

38. The masses of two similar solids are 32 kg and 108 kg respectively. If the surface area of the 2

smaller solid is 576 cm , find the surface area of the larger solid. 39. A cylindrical container has a circumference of 45 cm and a capacity of 6 capacity of a similar cylinder of circumference 36 cm.

2

[3]

1 litres. Find the 4 [3]

2

40. Two solid cones have curved surface areas of 8 m and 128 m respectively and the mass of the smaller one is 12 kg. Find the mass of the larger cone. [3]

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41. Three triangles T1 , T2 and T 3 are all similar to one another. The ratio of the lengths of a pair of corresponding sides in T1 and T2 is 2 : 5. The ratio of the lengths of a pair of corresponding sides in T2 and T 3 is 10 : 9. Find the ratio of the areas of [4] triangles T1 and T 3 . 42. If the diameter of a soap bubble increases by 30%, what is the percentage increase in its volume? [3] 43. The diagram shows a container in the form of an inverted cone with a base radius of 12 cm and a height of 28 cm. (a) Find the capacity of the container, taking π to be

22 7

.

(b) If water is poured into the container and the depth of water is 7 cm, find the volume of the water. [5]

44. In the diagram, AB and CD are the parallel sides of a trapezium ABCD. X is a point on AD such that AD = 5AX and Y is a point on BC = 5YC. (a) What is the value of the ratio

Area of ∆ABC

Area of ∆ABY

?

(b) Find the ratio of the area of ∆ABX and ∆ABD. (c) If the area of ∆ABY is 72 cm², find the area of ∆ABX.

[7]

45. The volume of a cube is 64 times that of another cube. (a) If the side of the smaller cube is 5 cm, find the side of the larger cube. (b) If the total surface area of the larger cube is 528 cm², find the total surface area of the smaller cube. [4] 46. One side of a polygon of area 72 cm² is 6 cm. Find the area of a similar polygon in which the corresponding side is 2 cm. [3] 47. A prism has a volume of 80 cm³. What is the volume of a similar prism whose height is 5 times the height of the given prism? [3]

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48. In the diagram, N is the mid-point of PR, L is a point on QR such that QR = 3QL and MN is parallel to LP. Find the ratio of the area of ∆OQL to the area of quadrilateral OLRN. [3] 49. In the diagram, X, Y and Z are points on sides PQ, QR and RP of ∆PQR respectively. (a) Given that ∆PQY and quadrilateral XQYZ have equal areas, (I) show that ∆PXY and ∆XYZ have equal areas. (ii) explain why XY is parallel to PR. (b) If it is given further that PX = 3 cm, XQ = 7 cm and the area of ∆PQR is 20 cm², find the area of quadrilateral XQYZ.

[6]

50. Two cones have base radii 12 cm and 18 cm, and vertical heights 22 cm and 33 cm. (a) If the curved surface area of the smaller cone is απcm 2 , find the slant height of the larger cone in terms of α . (b) If the volume of the larger cone is V cm³, express the volume of the smaller cone in terms of V. [4] 51. Two similar cones have diameter 15 cm and 12 cm respectively. If the total surface area of the first cone is 300 cm², find the total surface area of the second cone. [3] 52. Two similar glasses have heights 9 cm and 12 cm respectively. If the capacity of the smaller glass is 360 cm², find the capacity of the bigger glass. [3] 53. A marble statue of height 3 m weighs 54 kg. What is the weight of a similar marble statue if its height is 2 m? [3] 54. Two similar biscuit tins have volumes of 6 400 cm³ and 2 700 cm³. If the height of the first tin is 14 cm, find the height of the second tin. [3] 55. Two similar cups have volumes of 200 cm³ and 1 600 cm³. If the height of the second cup is 12 cm, find the height of the first cup. [3] 56. Two similar cakes of diameters 15 cm and 20 cm are sold at $12.00 and $26.00 respectively. Find out which cake is cheaper and by how much, to the nearest 10 cents. [3]

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57. A model of a cargo–ship is made on a scale of 1:30. If the volume of the model is 2 m³, what is the volume of the actual ship? [3] 58. Two watering cans are of the same shape. The smaller one is 45 cm high and can 1

hold 4 litres of water. If the larger one is 60 cm high, how much water can it 2

hold?

Teachers’ Resource NSM 3

[3]

© Oxford University Press

Answers 1. 320 g

2. (a) 198 cm

3. 3 240 cm

2

(b) 24 cm

3

4. (a) 4:9

(b) 8:27

5. (a) 3:7

(b) 27:343

6. 2 × 10

−4

3

m

3

7. (a) 62 800 m

3

(b) 62.8 m

8. (a)1:27

(b) 13.5 litres

9. (a) 1:4

(b) 49 cm

3

2

10. 7:8

11. (a) 100 cm

12. (a) 3 m

2

(b) 84 cm

2

(c) 60 cm

2

(b) 1 800 kg

13. (a) 40 cm

14. (b) 17.92 cm 2 (c) (i) 5 2 (d) 150 cm

(b) 375 cm

(ii)

Teachers’ Resource NSM 3

3

4 25

© Oxford University Press

15. (a) 1 244.23 m (b) 5 278.56 m

2 3

2

(c) 17.92 m , 9.12 m

16. (a) $4 320

17. (a) 36 cm

18. (a) 2:5

3

(b) 5 184 kg

(b) 4:9

(c) $12

(b) 40 ml

19. (a) 3:1

(b) 27:1

20. 5:6

21. (a) 4

1

cm

(b) 48 cm

2

(c) 14 cm

2

2

22. (a) 3:5

23. 625 cm

(b) 59.4 cm

3

24. (a) 3 cm

25. 180 cm

26. 14

3

(b) 640 g

2

5 2 cm 8

27. 16.75 cm

2

28. 36 litres

29. (a) 16.2 kg

(b) 19 cm

30. $200

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31. $3.30

32. 26 cm

33. (a) 16 cm

3

(b) 4:1

34. 3 kg

35. 2 880 cm

36. 16 cm

2

37. 704 cm

3

38. 1 296 cm

39. 3

2

2

1 litres 5

40. 768 kg

41. 4:9 42. 119.7% 43. (a) 4 224 cm³ 44. (a)

(b)66 cm³

5

(b)

4 45. (a) 20 cm

1

(c) 18 cm²

5 (b) 33 cm²

46. 8 cm² 47. 10 000 cm³ 48.

1 5

49. (b) 14cm²

Teachers’ Resource NSM 3

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3a

50. (a)

cm

(b)

44

8

Vcm³

27

51. 129 cm² 52. 853

1 3

cm³

53. 16 kg 54. 10

1 2

cm

55. 6 cm 56. The second cake and it is cheaper by $2.40. 57. 54 000 m³ 58. 10

2 3

litres

Teachers’ Resource NSM 3

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Chapter 10

Secondary 3 Mathematics Chapter 10 Trigonometrical Ratios ANSWERS FOR ENRICHMENT ACTIVITIES

Just For Fun (pg 272)

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Secondary 3 Mathematics Chapter 10 Trigonometrical Ratios GENERAL NOTES Teachers may wish to introduce one trigonometrical ratio at a time especially for weaker students. For brighter students, all three trigonometrical ratios can be introduced at one time. To help students to memorise these trigonometrical ratios more easily, teachers may wish to introduce the mnemonics, TOA-CAH-SOH which can be made to sound like “big–foot lady ” in the Fujian dialect. Plenty of practice should be given to identify the opposite, adjacent and hypotenuse sides with reference to a given angle as many students may find these confusing at the initial stage. When using the calculator, students must always be reminded to check that the mode is in ‘degree’. A mnemonic for the angle of elevation and the angle of depression is shown in the following story:

Draw on the board or a transparency the picture of a monkey playing in a tree and a weary hunter with a gun. The hunter has been looking for animals without much success for many hours. Suddenly he hears the noise from a monkey up in a tree in front of him. His gaze that was straight initially is now raised through an angle to spot the monkey. He is elated by the sight of the monkey (hence, the angle of elevation). The monkey, which is busily looking ahead for a mate of the fairer sex, hears the click of the gun. He looks down at an angle and is very depressed to see the hunter's gun (hence, the angle of depression). The Geometers’ Sketchpad (GSP) can be used to illustrate the various trigonometrical ratios.

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XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Secondary 3 Mathematics Test Chapter 10 Trigonometrical Ratios 1. Given that ∠A is an acute angle such that cos A = to the nearest degree.

12 , construct ∠A and measure its value correct 13 [3]

5 and that θ is an acute angle, write down the values of 13 (b) tan (90 – θ)

[4]

3 where θ is acute, find the numerical value of 2 sin θ + 5 tan θ , giving 5 your answer as a fraction in its lowest terms.

[4]

12 and θ is an acute angle, find the numerical values of 13 (b) 3 tan θ

[3]

2. Given that sin θ = (a) cos θ

3. Given that cos θ =

4. Given that sin θ = (a) 2 cos θ

5. If sin θ =

12 where θ is acute, find the values of (a) cos θ 13 (b) tan (90 – θ)

6. If sin θ =

7 where θ is acute, find the value of 2 cos θ + 3 tan (90 – θ). 25

7. Given that tan x = (a) 2 sin x,

5 where x is an acute angle, find the values of 12 (b) 3 cos x – sin x + tan x.

[2] [2]

[4]

[4]

15 and x is acute, find the value of each of the following, giving your answer as a fraction 17 in its lowest terms. (a) tan x + 2 cos x [2] (b) 3 cos x – 2 sin x [2]

8. If sin x =

Teachers’ Resource NSM 3

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40 where θ is acute, find the value of 2 cos θ + 3 tan (90 – θ), giving your answers as 41 a fraction in its simplest form. [4]

9. If sin θ =

10. If tan θ = 2

11. If tan θ =

2 where θ is acute, find the values of (a) 2 sin θ 5 (b) cos (90 – θ)

[2] [1]

a , where θ is acute and a and b are positive, find, in terms of a and b, the values b

of (a) sin θ (b) cos θ

12. If cos x =

[2] [2]

8

where x is acute, find the value of each of the following, giving your answer as a fraction 17 in its lowest terms. (a) 2 tan x + 3 sin x (b) 3 sin x – 4 tan x [4]

13. In the diagram, AB = 5 cm, ∠ABC = 90° and ∠BAD =∠CAD = 30°. Using as much of the information below as possible, calculate (a) CD (b) AC [Given that sin 30° = 0.5 = cos 60°, sin 60° = cos 30° = 0.87, tan 30° = 0.58 and tan 60° = 1.73.]

Teachers’ Resource NSM 3

[2] [1]

© Oxford University Press

14. The diagram shows a wheel of radius 20 cm in contact with the horizontal ground at A and touching the vertical step at C. Calculate (a) AB (b) BC [Given that sin 60° = 0.87, cos 60° = 0.5, tan 60° = 1.73.]

15. In the figure, ∠ABC = 90°, AB = (x – 2)cm, BC = (2x – 3)cm and AC = (3x – 7)cm. Calculate (a) the value of x, (b) ∠BAC

[2] [2]

[3] [2]

16. The lengths of the two diagonals of a rhombus are 32 cm and 16 cm respectively. Calculate the length of a side of the rhombus, giving your answer correct to 2 decimal places. [4]

17. The angle of depression of a boat 58.5 m from the base of a cliff is 35.6°. How high is the cliff? (Give your answer correct to 1 decimal place.) [3]

18. From a window 45 m high in a building, the angle of depression of a bus–stop is 36.7°. Calculate the distance of the bus–stop from the foot of the building. [3] 19. In ∆ ABC, AB = 14.6 cm, ∠ACB= 48.9° and the length of the perpendicular from A to BC is 9.4 cm. Calculate the area of ∆ ABC. [5]

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20. In ∆ ABC, AB = BC = 15.4 cm and ∠ABC = 54°. Calculate the area of ∆ ABC.

21. In the figure, AB = AC, ∠ADB = 90°, ∠BAC = 48° and AD = 8.4 cm. Calculate (a) BD, (b) CD.

[2]

[4]

22. In the figure, ∠ABD = 90°, AB = 12 cm, AC = 13 cm and CD = 4 cm. Calculate (a) AD, (b)∠ACB (c)∠CAD

[3] [2] [3]

23. In the diagram, ∠ADC = ∠ABD = 90°, AD = 6 cm and ∠BCD = 32°. Calculate (a) BD (b) AC (c) CD

[2] [3] [2]

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24. The sides of a right–angled triangle are 2x cm, (3x – 1) cm and (3x + 1)cm. (a) Form an equation in x and solve it to find x. (b) With the value of x, find the perimeter and the area of the triangle.

[4] [3]

27. In the figure, ∠ABC = 90°, ∠ADB = 28°, AC = 23 cm and AD = 38 cm. Calculate ∠BAC.

[4]

28. In the diagram, ∠ABC = 90°, BC = 8 cm and KB = 5 cm. (a) Calculate the length of CK, giving your answer correct to 2 decimal places. (b) Write down the numerical value of tan∠CKB. (c) Given that 2AK = 3KB, calculate the size of ∠CAB and the length of AC.

[2] [1] [5]

29. In the diagram, AB = 11 cm, BC = 6 cm, CD = 3 cm and BDC = 90°. Calculate (a) BD (b) AC (c)∠ABC (d) the area of ∆ ABC

[2] [2] [2] [2]

Teachers’ Resource NSM 3

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30. In the figure, ∠BCD= ∠ADB = 90°, AD = 6.9 cm, BD = 14.2 cm and BC = 8.2 cm. Calculate∠ABC. [4]

31. In the figure, ∠ABX = 90°, AB = 4 cm, BC = 5 cm, AX = 6.2 cm and XY = 6.4 cm. Calculate (a) CY, (b). ∠BCY

32. In the figure, ∠ABC = 90°, BC = 8.7cm, AC = 13.8 cm and X is the mid–point of AB. Calculate the length of CX , giving your answer correct to 1 decimal place.

[3] [3]

[4]

33. In the figure,∠ABD =∠BCD = 90°, AB = 18.9 cm, AD = 23.7 cm and BC = 8.3 cm. Calculate the length of CD, giving your answer correct to 2 decimal places. [4]

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34. At the point A, the angle of elevation of a ship from the top of a cliff is 21°. After sailing for 200 m towards the cliff, the angle of elevation becomes 43°. Calculate the height of the cliff. [6]

35. In the figure, ∠ABC =∠ ACE = ∠CDE = 90°. AC = 8.4 cm, CE = 9.2 cm, and ∠BAC = 52°. Calculate (a) BC, [2] (b) DE, [3] (c). ∠AEC [2]

36. The angle of elevation of the top of a building from a point on the ground 220 m away from the foot of the building is 16 o . What is the height of the building? [3] 37. A 5.2 m long ladder rests against the side of a house such that its foot is 1.7 m from the foot of the house. Find the angle at which the ladder makes with the horizontal. [3] 38. The angle of depression of a small boat from the top of a mast of a cruise ship is 9.8o . If the top of the mast is 76 m above the water level, find the distance from the boat to the top of the mast. [3] 39. A person, standing on the bank of a river, observes that the angle of elevation of the top of a tree on the opposite bank to be 48o . When he walks 30 m away from the bank, he finds the angle of elevation of the top of the tree to be 36o . Find the height of the tree and the width of the river. [5] 40. A boy standing in the middle of two flag poles 78 m apart finds that the angle of elevation of the tops of the flag poles from the point where he is standing are 34o and [4] 43o . Find the difference in the heights of the two flagpoles.

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41. Find the unknown sides (in cm) and angles indicated in each of the following figures: [12]

42. Find the angle of elevation of the top of a mast that is 35 m high from a point 28 m away from its foot on level ground. [3] 12 , find the value of each of the following, giving your answer as a 13 fraction in its lowest terms. (a) 2 cos x + 3 sin x (b) 3 tan x – cos x (c) 5 sin x – 4 tan x [5] (d) 2 sin x – cos x + tan x

43. If sin x =

44. The slant height of a right–circular cone measures 9.4 cm and the angle at the vertex is 68°. Calculate (a) the height of the cone, (b) the radius of the base.

[6]

45. From the top of a block of flats, the angle of depression of a car 45 m from the foot of the flat is 63°. Calculate the height of the flat. [3] 46. A tower 48 m high casts shadow 55 m long. Find the angle of elevation of the sun. [3]

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47. In the figure ABCD is a rectangle in which AB = 25.6 cm, ∠PAB = 48° and ∠PDC = 26°. Calculate (a) PC, (b) PD, (c) area of ABCD. [7]

48. In the figure, AB = 12 cm, BC = 5 cm, BD = 4 cm and BDC = 90°. Calculate at the length of AC and the angle ABC. [5]

49. The angle subtended at the centre of a circle by a chord of length, 18 cm is 120. Find the distance between the chord and the centre. [3] 50. Find the length of the wire supporting a pole in the given figure.

[3]

51. In the figure, AC = BC, CD = 22 cm and ∠ ABC = 65°. Calculate the perimeter and area of triangle ABC. [6]

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52. Calculate the hypotenuse of a right-angled triangle whose other sides are 6.2 cm and 8.4 cm. Also calculate the values of the other two angles. [6] 53. If the altitude of an isosceles triangle is 40 cm and the length of its base is 30 cm, find the vertical angle and the perimeter. [4] 54. For the given figure, calculate (a) AC, (b) BD.

[5]

55. From a point 20 m away from the foot of a building, the angles of elevation of the top and bottom of a flagpole which stands on the top of the building are 44° and 36° respectively. Find the height of the flagpole. [6]

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Answers 1.

23º

2.

(a) 12/13 (b) 2 2/5

3.

8 4/15

4.

(a) 10/13 (b) 7 1/5

5.

(a) 5/13 (b) 5/12

6.

12 36/175

7.

(a) 10/13 (b) 2 125/156

8.

(a) 2 111/136 (b) –6/17

9.

1 187/1 640

10.

(a) 1 11/3 (b) 12/13

11.

(a)

(b)

12.

a a2 + b2

b a + b2 2

(a) 6 27/68 (b) –4 29/34

13. (a) 29° 14.

(a) 10cm (b) 17.3cm

15.

(a) 4 ½

(b) 240 thousand tonnes

(b) 67.4º

Teachers’ Resource NSM 3

© Oxford University Press

16.

17.89cm

17.

41.9m

18.

60.4m

19.

81.55cm2

20.

95.9cm2

21.

(a) 9.33cm (b) 4.15cm

22.

(a) 15cm (b) 67.4º (c) 14.3º

23.

(a) 5.09cm (b) 11.3cm (c) 9.60cm

24.

(a) (2x)2 + (3x – 1)2 = (3x + 1)2 =, x =3 (b) 24cm, 24cm2

25.

(-2, 2)

26.

(a) 14.25cm (b) 52.3º (c) 22.74cm

27.

39.1º

28.

(a) 9.43cm (b) 1 3/5 (c) 32.6º (d) 14.84cm

29.

(a) √27 = 5.20cm (b) 12.7cm (c) 91.8º (d) 33cm2

30.

80.6º

31.

(a) 12.2cm (b) 65.8º

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32.

(a) 10.2cm

33.

11.64cm

34.

130.5m

35.

(a) 6.62cm (b) 7.25cm (c) 42.4º

36. 63.1o 37. 70.9o 38. 446.5 m 39. Ht of tree = 63.0 m, width of river = 56.8 m 40. 10.06 m. 41. (a) x = 9.26 cm, y = 11.92 cm

(b) x = 26.48 cm, y = 79.1°

(c) x = 59.2°, y = 32.5°, z = 7.0 cm (d) x = 68.4°, y = 18.5 cm, z = 11.8 cm 42. 51.3° 43. (a) 3

7 13

44. (a) 7.79 cm

(b) 6

53 65

(c) −4

64 65

(d) 3

56 65

(b) 5.26 cm

45. 88.3 m 46. 41.1° 47. (a) 12.5 cm

(b) 28.5 cm

(c) 408 cm²

48. 14.3 cm, 107.4o 49. 5.2 cm 50. 7.55 m 51. 69.1 cm, 225.7 cm2 52. 10.44 cm, 36.4o, 53.6o

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53. 41.1o, 115.4 cm 54. (a) 11.66 cm

(b) 13.81 cm

55. 4.78 m

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Chapter 11

Secondary 3 Mathematics Chapter 11 Further Trigonometry ANSWERS FOR ENRICHMENT ACTIVITIES Exploration (pg 308) Join B to O and C to O. Join O to P, the mid-point of BC. Let R be the radius of the circle. 1 BÔC = 2A, ∴PÔC = A and PC = a. 2 1 2a PC a In ∆POC, sin A = OC = R = 2R a ∴ 2R = sin A Similarly, by joining A to O and using the same reasoning, b c we can prove that 2R = sin B = sin C

Just For Fun (pg 321) These 3 figures are impossible to construct in real life.

Exploration (pg 304) Heron’s Formula for the area of a triangle Consider ∆ABC with sides a, b, and c. Let 2s be the perimeter of ∆ABC, hence 2s = a + b + c. s is then known as the semi-perimeter of the triangle. Applying the Cosine Rule, cos A =

b2 + c2 − a2 2bc

and using the identity sin2 A + cos2 A = 1 ∴ sin2 A = 1 – cos2 A = (1 + cos A)(1 – cos A) Substituting for cos A,

b2 + c2 − a2 b2 + c2 − a2 } { 1 – } 2bc 2bc 2 2 2 2 2 2 2bc + b + c − a 2bc − b − c + a }{ } = { 2bc 2bc 2 2 2 2 2 b + 2bc + c − a −(b − 2bc + c ) + a2 } { } = { 2bc 2bc 2 2 2 2 (b + c) − a −(b − c) + a = { } { } 2bc 2bc

sin2 A = { 1 +

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= {

(b + c + a)(b + c − a) (a + b − c)(a − b + c) }{ } 2bc 2bc

Now a + b + c = 2s (perimeter of ∆ABC) Hence b + c − a = a + b + c − 2a = 2s – 2a a + b – c = a + b + c – 2c = 2s – 2c a – b + c = a + b + c – 2b = 2s – 2b Substituting into sin2 A, we have sin2 A =

2s⋅2(s − a)⋅2(s − c)⋅2(s − b) 4b2c2

∴ sin A = ±

4s(s − a) (s − b) (s − c) b2c2

2

sin A = bc s(s − a) (s − b) (s − c) 1

i.e. 2 bc sin A = s(s − a) (s − b) (s − c) 1

But area of ∆ABC = 2 bc sin A ∴Area of ∆ABC = s(s − a) (s − b) (s − c)

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Secondary 3 Mathematics Chapter 11 Further Trigonometry GENERAL NOTES

The trigonometrical ratios of obtuse angles are important in this course. To help pupils have a better understanding of the concepts, teachers should derive the formulas for the sine and cosine rule. Pupils are also encouraged to use the Geometer’s Sketchpad (GSP) to derive the sine rule using the Thinking Skill: Inferring. For pupils doing Additional Mathematics, this topic can be taught concurrently, covering angles from 0o to 360o. Pupils sometimes find difficulty in deciding whether to use the sine or cosine rule to solve a triangle. Plenty of practice should be given to the pupils to help them decide which rule would be most suitable to solve triangles. The triangles below may be used for the purpose.

(i) (ii) (iii) To help pupils gain a better perspective of 3-D problems, wire models with strings or rods are useful tools to illustrate the triangles and angles involved. 2-D diagrams are unable to illustrate 3-D shapes effectively, e.g. the square faces of a cube. Thus it will be helpful to draw separate 2-D diagrams showing exact shapes of triangles and angles where they are needed. The use of available materials such as set-squares, ruler, pencils, etc. to set up 3-D diagrams for better understanding is helpful to pupils especially during examination times.

The above diagram shows how a set square and a few pencils are used to show a ∆ABC rightangled at B and a vertical post BT standing at B. Common Errors Pupils should be reminded to set the mode of their calculators to “Degree”. Pointing out that use of angles in radians will be covered in the next chapter. Many pupils also fail to remember the formula correctly during test or examination time. One way to correct this mistake would be to insist that they write down the formula for each sum that they do.

Teachers’ Resource NSM 3

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XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: 35 min

Class: _______

Marks: 18 Secondary 3 Multiple-Choice Questions Chapter 11 Further Trigonometry

1. PQRS is a parallelogram where PQ = 4 cm, QR = 6 cm and PQˆR = 60°. Find the area of the parallelogram in cm 2 . (A)6 3 (C) 12 3 (E) 24

(B) 12 (D) 20 ( )

2. The value of PR 2 in the diagram above is (A) 24

(B) 28

(C) 52

(D) 76

(E) 82 ( )

3. The length of the sides of a triangle are 8 cm, 12 cm and 15 cm. The triangle must be (A) isosceles (D) obtuse angled

(B) acute angled (E) equilateral

(C) right-angled ( )

4. In the figure, AB = AC and BC > AB . State which of the following is true. I. x > 60

II. y < x

III. y > 60

(A) I only (B) II only (C) III only (D) I and II only (E) II and III only 5. If x is acute and tan x = (A)

1 3

(B)

Teachers’ Resource NSM 3

1 , then the value of cos x is 2 2 3 (C) (D) 3 3 2

( )

(E)

1 5

( )

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6. In ∆ PQR , PRˆQ = 57°, QR = 6.2 cm and PR = 7.8 cm. To find the length of PQ , we can use the (A) sine rule (D) tangent ratio

(B) cosine rule (E) area formula

(C) Pythagoras’ Theorem ( )

7. If 45° < x < 90°, which of the following is true? (A) tan x < cos x < sin x (C) sin x < cos x < tan x (E) sin x < tan x < cos x

(B) cos x < tan x < sin x (D) cos x < sin x < tan x ( )

8. In ∆ ABC , AB = 17 cm, AC = 8 cm and BC = 15 cm. The area of ∆ ABC is (A) 15 cm 2

(B) 30 cm 2 (C) 68 cm 2 (D) 120 cm 2 (E) 60 cm 2

( )

9. In ∆ PQR , PQˆR = 30°, PQ = 8 cm and QR = 10 cm. The area of ∆ PQR is (A) 10 cm 2 (E) 20 3 cm 2

(B) 10 3 cm 2

(C) 20 cm 2

(D) 30 cm 2 ( )

10. In the figure, ABˆC = 60°, AB = 4 cm, BC = 10 cm, CD = 6 cm and AD = 5.5 cm. ˆC. Find the value of AD (A) 60° (C) 101.5° (E) 125°

(B) 98.5° (D) 120°

( ) 11. The figure shows a cube. Which of the following is/are true? (I) GÂC = 45° (III) HÂB = 90°

(II) ACˆH = 60°

(A) I only (C) III only (E) II and III only

(B) II only (D) I and III only ( )

Teachers’ Resource NSM 3

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12. In the figure ABCD , ABEF and CDFE are rectangles. Given that CDFE is perpendicular to ABCD , CE = 10 cm, EÂC = 30° and EBˆC = 45°, calculate the length of AB . (A) 10 cm (C) 10 3 cm (E) 20 2 cm

(B) 10 2 cm (D) 20 cm ( )

13. In the figure, OBC is a right-angled triangle in a horizontal plane with BÔC = 90°. OA is vertical, ABˆO = θ°, BCˆA = α° and OC = 8 cm. The length of AB is given by 8 sin α sin θ 8 tan α (D) cos θ

(A)

8 sin θ sin α 8 tan θ (E) cos α

(B)

(C)

8 cos α tan α ( )

14. The figure shows a cube. Find AFˆH . (A) 30° (C) 60° (E) 90°

(B) 45° (D) 75°

( )

15. From the top of a building 100 m high, the angles of depression of two cars P and Q are 30° and 45° respectively. If P is due south and Q is due east of the building, find the distance in metres between P and Q . (A) 200 m

(B) 158 m

(C) 120 m

(D) 115 m

(E) 72 m

( )

16. The figure shows a rectangular cuboid with AB = 8 cm, BC = 6 cm and CG = 5 cm. The value of GÂC is (A) 26.6° (C) 30° (E) 66.7°

(B) 29.5° (D) 33.3° ( )

Teachers’ Resource NSM 3

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17. The angle of elevation of the top of a tower, from a point A on the horizontal ground north of the building is 45°. From another point B, 50 m east of A, the angle of elevation becomes 30°. Find the height of the building in metres. (A) 25

(B) 25 2

(C) 25 3

(D) 50

(E) 50 2

( )

18. The figure shows a right pyramid with a square base ABCD of length 20 cm. If the length of a slant edge VA is 26 cm, find VÂC correct to the nearest degree. (A) 29° (C) 33° (E) 60°

(B) 30° (D) 57°

( )

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. C 6. B 11. E 16. A

2. B 7. D 12. B 17. B

Teachers’ Resource NSM 3

3. 8. 13. 18.

D E D D

4. D 9. C 14. C

5. B 10. B 15. A

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XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Secondary 3 Mathematics Test Chapter 11 Further Trigonometry 1. In the diagram, APB is a straight line,

ABˆ C = 90°, AC = 17 cm, AP = 9 cm and area of ∆APC = 36 cm2. Calculate (a) BC, (b) tan CPˆ B .

[1] [2]

2. In the diagram, AB = 12 cm, BC = 9 cm,

ABˆ C = 90°, CD = 11 cm and AD = 19 cm. Calculate the value of (a) sin θ (b) cos α. Give your answers as a fraction in its lowest terms. [3]

3. In the figure, AB = 12 cm, BC = 5 cm and

ABˆ C = 90°. (a) Find the value of sin BÂC. [2] (b) A circle is to be drawn so that it will pass through A, B and C. Write down the radius of the circle. [1]

Teachers’ Resource NSM 3

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4. In the diagram, ABCD is a quadrilateral in which AD = 6 cm, DC = 8 cm, AC = 7 cm, BC = 5 cm and ACˆ B = 65°. Calculate (a) ACˆ D . (b) the area of the triangle BCD.

[2] [2]

5. Three points P, Q and R are such that the bearing of R from P is 125°, the bearing of Q from P is 205°, and PQ = PR. Calculate (a) the bearing of P from R, [1] (b) the bearing of P from Q, [1] (c) the length of PQ given that QR = 20 m. Give your answer correct to 1 decimal place. [2] [Given sin 40° = 0.64, cos 40° = 0.77, tan 40° = 0.84]

6. In the diagram, triangle PQS has a right angle at P, and R is a point on PS such that

PRˆ Q =30°. Given that PQ = 5 cm, and QS = 13 cm, (a) find sin PQˆ S , [2] (b) find the length of SR, giving your answer [3] in the form a + b 3 cm.

7. In the triangle ABC, AB = 6.4 cm, AC = 8.3 cm, and BÂC = 42.6°. Find the length of BC and the area of ∆ABC. [5]

8. In ∆ABC, K is a point on BC such that BK = 3.6 cm and CK = 4.8 cm. Given that the area of ∆ABK = 9 cm2 and sin ABˆ C = 0.5, calculate (a) the area of ∆AKC, [1] (b) the length of AB. [2]

Teachers’ Resource NSM 3

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9. A ship, P, locates a lighthouse, Q, on a bearing of 300°, and another lighthouse, R, on a bearing of 030°. If PQ = 16 km and PR = 12 km, find the distance of QR. [3]

10. In the diagram, the bearing of B from A is 072°, and the bearing of C from B is 146°. If AB = BC, find the bearing of (a) A from B, (b) A from C.

[2] [2]

11. In the diagram, AQ = 6 cm, QC = 3 cm, AP = 4 cm, PB = 8 cm and the area of ∆APQ = 10 cm2. Calculate (a) sin PÂQ, (b) the area of the quadrilateral BPQC.

[2] [2]

12. In the diagram, QRS is a straight line. PQ = 24 cm, QR = 7 cm and PR = 25 cm. (a) Explain why PQˆ R = 90°. (b) Express each of the following as a fraction and write down the value of

[1]

(i)

sin QPˆ R

[1]

(ii)

tan PRˆ Q

[1]

(iii)

cos PRˆ S

[1]

13. In the diagram, the bearings of two ships P and Q from a lighthouse L are 030° and 110° respectively. Given that P is 28 km from Q and that the bearing of Q from P is 138°, find (a) the distance of Q from L, (b) the bearing of L from Q.

Teachers’ Resource NSM 3

[3] [1]

© Oxford University Press

14. A ship steams 30 km from a port P on a bearing of 050° to the point Q and then 30 km on a bearing of 015° from port Q to the port R. (a) Find the bearing of port R from port P, [2] (b) Calculate the distance of PR. [2] (c) Calculate the shortest distance from Q to the line joining P and R. [2]

15. In the diagram, AB = BC = BD = 10 cm and

BCˆ D = 52°. Calculate (a) ADˆ B , (b) the length of CD, (c) the length of AD.

[2] [3] [3]

16. The figure shows a point A which lies 9 km south of point B. The points C and D are both 6 km from B and the bearing of C from A is 036.3°. The points A, C, D and E all lie on a straight line. Calculate (a) (b) (c) (d)

ACˆ B ,

[3] [1] [2]

the bearing of C from B, the length of CD, the shortest distance from B to the line ACD. [2]

17. In the figure, the points A, B and C form an equilateral triangle, and the bearing of B from A is 042°. Find (a) the bearing of C from A, (b) the bearing of C from B.

Teachers’ Resource NSM 3

[1] [2]

© Oxford University Press

18. In the diagram, ABˆ C = ACˆ D = 90°, BÂC = 40°, AC = 6.8 cm and CD = 8.2 cm. Calculate (a) AB (b) cos ADˆ C (c) sin ADˆ T

[2] [2] [2]

19. A ship sails 7.8 km from P to Q. It then sails another 6.7 km from Q to R. The ship finally sails from R to a point S, which is due north of Q. Given that PQˆ R = 140°, RQˆ N = 74° and RSˆQ = 42°, calculate (a) (b) (c) (d) (e)

the bearing of P from Q, the bearing of Q from R, the distance of PR, the distance of RS, the shortest distance from Q to the ship as it sails from P to R.

[1] [2] [3] [3] [3]

20. The points P, Q and R are on level ground such that Q is due north of P, the bearing of R from P is 018° and the bearing of R from Q is 063°. (a) Given that the distance PQ = 250 m, calculate (i) the distance QR, [3] (ii) the bearing of P from R. [3] (b) Given that the vertical post XQ is 32 m high, calculate the angle of elevation of X from P. [2]

21. In the figure, ABˆ C = BCˆ D = 90°, BÂC = 42.7°, BC = 7 cm and CD = 9.6 cm. Calculate (a) BDˆ C , (b) the length of AC, (c) the length of BD.

[2] [2] [2]

Given that K is a point on BD such that CK is perpendicular to BD, calculate (d) the length of CK. [3]

Teachers’ Resource NSM 3

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22. From a lighthouse A, the bearing of two ships B and C are 046° and 320° respectively. If AB = 458 m and AC = 625 m, calculate the distance of BC and the bearing of B from C. [5]

23. (a) In the figure, O is the centre of the sector BOC. Given that BÔC = 124°, BÂO = 34.5°, AÔB = 90° and OC = 6.8 cm, calculate (i) (ii) (iii)

AO, AB, the area of sector BOC.

[7]

(b) Three points A, B and C lie on level ground. The bearing of B from A is 057° and the bearing of C from A is 126°. If BC = 84 m and AB = 65 m, find the bearing of B from C. [5]

24. In the diagram, OA = OB = 80 m, OC = 70 m, the bearing of A and B from O are 052° and 144° respectively. (a) Calculate the bearing of B from A. [2] (b) Calculate the length of AC. [3] (c) A man walks from A to C until he reaches a point P where OP is a minimum. Calculate the length of AP. [3] 25. In the diagram, ABˆ D = BDˆ C = 90°, BÂD = 42°, BD = 5.8 m and CD = 3.2 m. Calculate (a) AD, (b) CBˆ D , (c) BC. Given that X is a point on AD such that AX = 5.5 m, (d) calculate the area of ∆ABX. [6]

Teachers’ Resource NSM 3

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26. (a) Solve the equation 5x2 + 2x = 9, giving your answer correct to 3 significant figures. [3] (b) In the diagram, AB = (y – 1) cm, BC = (x – 2) cm, CD = (2x – 3) cm, AD = (y + 2) cm, BD = (3x – 7) cm and BCˆ D = 90°. (i) Using the right-angled triangleBCD, form an equation in x, and hence find the value of x. [3] (ii) If BD = AD, use your result in (i) to find y, and hence find ADˆ B . [3] (iii) Find the area of ∆ABD. [3]

27. In the diagram, Q Pˆ S = PRˆ S = 90°, QSˆP = 43.7°, PR = 14 cm and PS = 19.2 cm. Calculate (a) QSˆR , (b) PQ, (c) QS.

[2] [2] [2]

28. ABCD is a parallelogram in which BC = 13 cm. H and K are points on DC and AB such that AK = 12 cm, KB = 9 cm, and DH = 5 cm. Calculate (a) AH,

[1]

(b) ABˆ C ,

[2] (c) the area of ∆KBL, where L is a point on BC such that LC = 8 cm. [3] (d) the ratio of the area of ∆ADH to the area of ∆ACK. [1]

29. In the diagram, ABCD is a rectangle, and DQ is perpendicular to CP. Given that BC = 15 cm, PB = 8 cm, PQ = 5 cm and DQ = 28 cm, calculate

(a) (b) (c)

CQ, AB,

ADˆ Q .

Teachers’ Resource NSM 3

[6]

© Oxford University Press

30. AB and CD are two roads which meet at X. AB runs in a north-south direction and makes an angle of 38° with CD. At 09 45, a car P, which is heading south towards B, is 315 km north of the point X. At the same time, a truck Q, travelling along CD, is 200 km N 38°E of X. Given that the car P is travelling at 75 km/h, and the truck Q is travelling at 60 km/h, calculate (a) the time at which the car passes X, [2] (b) the distance between P and Q at 09 45, [3] (c) the distance of P from X, and the distance of Q from X, at 15 57, [3] (d) the bearing of Q from P at 15 57, giving your answer correct to the nearest degree. [4]

31. The figure shows the positions A, B, C and D of four oil rigs. C, A and D lie in a straight line. Given that AD = AB = 60 km, CÂB = 115°,

ABˆ C = 35° and B is due east of C, calculate (a) the distance of CB, [3] (b) the distance of BD. [3] A supply ship S sets sail from C to B in a straight line. (c) Find the distance the ship S must move such that it will be closest to A. [3]

32. In the diagram, AB = CD = 3 cm and BC = DE = 2 cm. Calculate (a) the length of BE, (b) the length of AD, (c) the values of x and y.

[2] [2] [4]

33. In the diagram, AB = 12 cm, AD = 5 cm, BC = 7.2 cm, BÂD = 90° and DBˆ C = 70°. Calculate (a) the length of BD, (b) the length of CD, (c) the area of ∆DBC.

Teachers’ Resource NSM 3

[2] [4] [3]

© Oxford University Press

34. P, T, Q, R and S are points on the semicircle with centre O and PS diameter. The radius of the semicircle is 8.5 cm, the chord PQ is 8 cm and QSˆR = 34°. Calculate (a) QÔR, [1] (b) the length of the chord QS, [2] (c) the area of ∆PQS, [2] (d) the perpendicular distance from Q to PS, [2] (e) QPO, [2] (f) the area of the minor segment PTQ. [3] 35. In the figure, BCˆ D = 90°, BÂD = 37°, DBˆ C = 45° and AB = 20 m. Find the length of CD. [5]

36. The figure shows a section of a wall. The faces ABCD and PQCD are rectangular with ABCD on the horizontal and PQCD vertical. Given that AB = 12 m, BC = 4 m and CQ = 3 m, (a) find the length of AQ,

[2]

(b) write down the numerical value of (i) (ii)

cos CBˆ Q , sin CÂQ.

[1] [1]

37. The diagram shows a rectangular vertical billboard being supported by straight wires AP, BQ and PB. Given that AB = 8 m, BC = 4 m and CQ = 6 m, (a) calculate the length of PC,

[1]

(b) write down the numerical value of (i)

tan BPˆ C ,

[1]

(ii)

sin DPˆ C .

[1]

Teachers’ Resource NSM 3

© Oxford University Press

38. The figure shows a pyramid with a horizontal rectangular base ABCD where AB = 8 cm, AD = 6 cm and the vertex V is 12 cm vertically above X. The mid-point of BC is M. Calculate (a) the length of VM, (b) tan VÂX,

[2] [1]

(c) sin AVˆX .

[2]

[Given that 10 = 3.16, 12 = 3.46]

153 = 12.37,

39. The legs of a camera tripod are each 60 cm long. When it stands on horizontal ground, the ends of the legs form a equilateral triangle of side 40 cm. Find (a) the height of the vertex V above the ground, [3] (b) the angle made by each leg with the ground. [2] 40. The figure shows a pyramid with a square base PQRS and vertex O. The diagonals of the base intersect at M. OP = OQ = OR = OS = 16 cm and PQ = 10 cm. Calculate (a) PR, (b) OM, (c) PÔR.

[2] [2] [2]

41. In the diagram, A, B, and C are three points on level ground. AT is a vertical pole of height 15 m, the angle of elevation of T from B is 40° and the angle of elevation of T from C is 55°. If BÂC = 65°, calculate (a) (b) (c) (d)

the length of AB, the length of AC, the area of ∆ABC, the length of BC.

Teachers’ Resource NSM 3

[2] [2] [2] [3]

© Oxford University Press

42. The figure shows a rectangular box of dimension 25 cm × 15 cm × 18 cm. (a) Calculate the length of AR, giving your answer correct to 1 decimal place. [3] (b) Find the angle that AQ makes with the horizontal i.e. QÂB. [2] (c) Find PCˆ A .

[3]

43. The diagram represents a solid in which the horizontal base ABCD and the vertical face PQDC are rectangles. Given that AB = 28 cm, BC = 22 cm and PC = 15 cm, calculate (a) the length of BD and BQ, giving your answer correct to 1 decimal place, [3] (b) the angle that the line BP makes with the [2] horizontal, i.e. PBˆ C , (c) the angle that the line of greatest slope BQ makes with the horizontal, i.e. DBˆ Q .

[2]

44. In the diagram, B is the foot of a vertical pole BT. A, B and C are on horizontal ground where AB = 75 m, BC = 112 m and BÂC = 90°. Given that the angle of elevation of T from A is 15°, calculate (a) (b) (c) (d)

the height of the pole, ABC, the shortest distance from A to BC, the angle of elevation of T from C.

Teachers’ Resource NSM 3

[2] [2] [2] [2]

© Oxford University Press

45. In the diagram, A, B, C and D are four corners of a rectangular block of dimension 18 cm by 8 cm by 14 cm and X is a point on BC such that AXˆB = CXˆD = x°. Calculate (a) the length of AD, (b) the value of x, (c) the length of BX.

[3] [3] [2]

46. The figure shows a horizontal ring with centre O and radius T cm being suspended from a point T by three strings TA, TB and TC, each of length 12 cm. Given that AÔB = 58° and X is the mid-point of AB, find (a) (b) (c) (d)

the length of TO, the angle of elevation of T from A, the length of OX, the angle of elevation of T from X,

(e) A Tˆ B .

[2] [2] [2] [2] [4]

47. The diagram shows a door of dimensions 2.2 m by 1.2 m turning through 40° from position ABCD to APQD. Calculate (a) the length of PB,

[3]

(b) the angle of elevation of C from P

[3]

(c) PDˆ B .

[3]

48. The diagram shows a triangle ABC lying in a horizontal plane. T is a pole vertically above B. Given that BC = 18 m, AT = 35 m, BAˆ T = 34° and ABˆ C = 65°, calculate (a) the length of AC, (b) the length of TC, (c) the angle of elevation of T from C.

Teachers’ Resource NSM 3

[4] [3] [2]

© Oxford University Press

49. In the diagram, A, B, C and D are four points on the corner of a rectangle. Given that AB = 16 m, BC = 18 m, X is the mid-point of AB and T is a point vertically above X. If TX = 15 m, calculate (a) (b) (c) (d)

CX, the angle of elevation of T from D, the angle of elevation of T from B, the length of CT.

[2] [2] [2] [2]

50. The figure shows three points A, B, and C with a vertical mast AT standing at A. The angle of elevation of T from B is 25°. Given that AB = 28 m, ABˆ C = 38° and BÂC = 80°, calculate (a) the height of the mast correct to 2 decimal places, [2] (b) the length of AC, [3] (c) the angle of elevation of T from C, [3] (d) the length of BC. [3]

51. In the diagram, A, B and C are three points on the horizontal plane. AT is a vertical tower. The angles of depression of B and C from the top of the tower are 35° and 18° respectively. Given that AB = 34 m and BÂC = 56°, calculate (a) (b) (c) (d) (e)

the height of the tower, [2] the length AC, [2] the area of ∆ABC, [2] the length of BC, [3] the greatest angle of elevation of T from a point on BC. [3]

Teachers’ Resource NSM 3

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52. In the diagram, BCDE represents a vertical rectangular billboard of height 3.5 m. A, B and C are three points on level ground such that BC = 8.8 m, BÂC = 80° and ACˆ B = 42°. P is a point on AB and Q is a point on AC such that BP = PQ = 3.2 m. (a) Calculate the lengths of AP and CP. [5] ˆ (b) Calculate the size of PQC . [3] (c) A cat walks along the top edge of the billboard from E to D. Find the largest possible angle of elevation of the cat from P. [3] 53. Three points X, Y and Z are on level ground. Y is due south of X and Z is due east of X. XT is a vertical flag pole and XY = 30 m. (a) Given that the angle of elevation of T from Y is 28°, calculate the height of the flag pole, giving your answer correct to one decimal place. [2] (b) The bearing of Z from Y is 042°. Calculate the distance of XZ and YZ. [4] (c) Calculate the angle of elevation of T from Z. [3] (d) A man walks from Y to Z. Calculate the distance he must walk to a point K on YZ so that the angle of elevation of T from K will be the greatest. [3]

1 54. Given that sin θ = 3 and 90° < θ < 180°, find the value of

(a) cos θ

(b) tan θ

[3]

55. Given that cos x° = sin y° = sin 25° and that x is acute and y is obtuse, find the value of x and of y. [3] 56. (a) If sin x° = sin 23° and 90 < x < 180, find x. (b) If cos x° = − sin 60° and 0 < x < 180, find x.

[3]

57. The diagram shows the positions of A, B and C. Find the bearing of (a) B from A, (c) C from B,

(b) C from A, (d) A from C.

Teachers’ Resource NSM 3

[4]

© Oxford University Press

58. In ∆ABC, AB = 7 cm, BC = 6 cm and AC = 8 cm. Find the value of cos BÂC, leaving your answer as a fraction in its lowest term. [3] 59. (a) In ∆ ABC, BÂC = 26°, ABˆ C = 61° and AC = 10 cm. Calculate the perimeter of ∆ABC, giving your answer correct to 3 significant figures. [3] (b) In ∆ PQR, PQ = 7.5 cm, PR = 8.8 cm and QPˆ R = 72°. Calculate the length of QR [3] and the value of cos PQˆ R . 60. In the diagram, AB = 7 cm, CD = 9.8 cm, ABˆ C = 57° and ACˆ D = 108°. Calculate (a) BC, (b) AC, (c) the area of ∆ ABD.

[7]

61. In ∆ABC, AB = 7.2 cm, AC = 8.8 cm and BÂC = 132°. Calculate (a) the length of BC,

(b) the area of ∆ABC.

[5]

62. Two ships leave a port at the same time. One sails at 22 km/h on a bearing of 047° and the other at 18 km/h on a bearing of 148°. Find the distance between the ships after 3 hours. [4] 63. The bearing of a point B from A is 023.2° and the bearing of C from A is 264°. Given that AB = 225 m and AC = 186 m, calculate (a) BC, (b) the bearing of C from B. [5] 64. In the diagram, QS and ST are perpendicular to PR and PQ respectively. Given that RQˆ S = 50°, PQˆ S = 60° and PQ = 8 cm, calculate the length of (a) RS,

Teachers’ Resource NSM 3

(b) PT.

[5]

© Oxford University Press

65. The diagram shows a rectangular cuboid where AB = 12 cm and AD = 20 cm, AE = 4 cm and P is a point on EF such that EP = 3 cm. Find (a) the length of AP, (b) tangent of PÂE, (c) PBˆF , (d) ABˆD . [8] 66. The diagram shows a pyramid with a rectangular base ABCD. It is given that AB = 16 cm, BC = 12 cm and V is vertically above the centre of the base N. If VN = 20 cm, calculate (a) the length of VA, (b) tan VÂN, (c) sin VBˆN , (d) AVˆC , (e) BVˆD . [10] 67. The diagram shows a rectangular pyramid TABCD where TDC is vertical. Given that AB = 5 cm, BC = 8 cm and TC = 13 cm, calculate (a) TÂD, (b) TBˆD .

[6]

68. P, Q and R are three points on level ground. V is a point vertically above P. PQ = 9 m, PV = 12 m and VR = 24 m. (a) Write down the sine of the angle between PR and VR. (b) Calculate PR. (c) Write down the tangent of the angle between PQ and VQ. (d) Given that PQˆR = 120°, calculate (i) PRˆQ (ii) the length QR.

Teachers’ Resource NSM 3

[10]

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69. The diagram shows 3 points A, B and C on level ground. T is a point vertically above B. Given that AB = 44 m, AC = 57 m, TB = 28 m and BÂC = 40°, calculate (a) TÂB, (c) TCˆB .

(b)

BC, [7]

70. The figure shows a cube with edges 4 cm long. ABCD is horizontal and X is the mid-point of the vertical edge CG. Calculate (a) sin XÂC, giving your answer as a fraction in its lowest term, (b) the angle of elevation of X from B, (c) AXˆE . [6]

71. The figure shows a horizontal plot of ground ABC with a vertical pole T standing at the corner A. Given that BÂC = 115°, AB = 28 m, BC = 65 m and the angle of elevation of T from B is 40°, calculate (a) the height of the pole, (b) the length of AC, (c) the length of TC. [8]

72. The figure represents a solid with a horizontal rectangular base ABCD and the vertical rectangular face PQDC. Given that AB = 45 cm, BC = 35 cm and PC = 25 cm, calculate (a) the angle of elevation of Q from A, (b) the angle of elevation Q from B, (c) the length of QB. [8]

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Answers 1

1. (a) 8

(b) 1 3

3

(b) −

2. (a) 5

5

1 22

3. (a) 13

(b) 6.5 cm

4. (a) 46.6°

(b) 18.6 cm2

5. (a) 305°

(b) 025°

12

(c) 15.6 m

(b) 12 − 5 3 cm

6. (a) 13 7. 5.63 cm ; 17.98 cm2

8. (a) 12 cm2

(b) 10 cm

9. 20 km

10. (a) 252°

(b) 289°

5

(b) 35 cm2

11. (a) 6

7

24

12. (b) (i) 25

(ii) 7

7

(iii) − 25

13. (a) 27.04 km

(b) 290°

14. (a) 032.5°

(b) 57.2 km

(c) 9.02 km

15. (a) 38°

(b) 12.3 km

(c) 15.8 km

16. (a) 117.4°

(b) 153.7°

(c) 5.52 km

17. (a) 102° km

(b) 162°

18. (a) 5.21

(b) 0.770

(c) 0.638

(c) 13.6 km

(d) 5.31 km

(ii) 198°

(b) 7.3°

19. (a) 146°

(b) 106°

20. (a) (i) 109.25 m

Teachers’ Resource NSM 3

(d) 5.33 km

(e) 2.46 km

© Oxford University Press

21. (a) 36.1°

(b) 10.3 cm

(c) 11.9 cm

(d) 5.66 cm

23. (a) (i) 9.89 cm

(ii) 12.0 cm

(iii) 50 cm2

(b) 352.3°

24. (a) 188°

(b) 141.9 m

(c) 76.22 m

25. (a) 8.67 m

(b) 28.9°

(c) 6.62 m , 11.85 m2

26. (b) (i) 4.5

(ii) 4.5 , 31.2°

(iii) 10.96 cm2

27. (a) 3.1°

(b) 18.3 cm

(c) 26.6 cm

28. (a) 12

(b) 67.4°

(c) 20.8 cm2

29. (a) 12 cm

(b) 30.46 cm

(c) 66.8°

22. 748.6 m ; 102.4°

30. (a) 13 57

(b) 199.8 km

5

(d) 12

(c) P, 150km Q, 172 km

31. (a) 108.8 km

(b) 64.5 km ; 59.6 km

32. (a) 5.39 cm

(b) 5.83 cm

(c) x = 40.0, y = 37.2

33. (a) 13 cm

(b) 12.5 cm

(c) 44 cm2

34. (a) 68°

(b) 15 cm

(c) 60 cm2

(e) 64.8°

(f) 3.94 cm2

1

(d) 7 17 cm

(d) 278°

35. 61.15 m

36.

(a)

4

13 m

3

(b) (i) 5 2

(ii) 13 4

37. (a) 10 m

(b) (i) 5

38. (a) 12.64 cm

(b) 2 5

39. (a) 55.4 cm

(b) 67.4°

40. (a) 14.14 cm

(b) 14.35 cm

(c) 52.5°

41. (a) 17.88 m

(b) 10.50 m

(c) 85.1 m2

42. (a) 34.3 cm

(b) 35.8°

(c) 31.7°

Teachers’ Resource NSM 3

2

(ii) 5 5

(c) 13

(d) 16.47 m

© Oxford University Press

43. (a) 35.61 cm, 38.64 cm

(b) 34.3°

(c) 27.8°

44. (a) 20.1 m

(b) 48.0°

(c) 55.7 m

45. (a) 24.2 cm

(b) 50.7°

(c) 6 11 cm

46. (a) 9.75 m (d) 57.9°

(b) 54.3° (e) 32.9°

(c) 6.12 m

47. (a) 0.82 m

(b) 69.5°

(c) 18.9°

48. (a) 26.9 m

(b) 26.6 m

(c) 34.1°

49. (a) 19.7 m

(b) 37.3°

(c) 61.9°

(d) 24.8 m

50. (a) 13.06 m

(b) 19.52 m

(c) 33.8°

(d) 31.23 m

51. (a) 23.8 m (d) 63.12 m

(b) 73.3 m (e) 46.1°

(c) 723.1 m2

52. (a) 2.78 m, 7.60 m

(b) 121.2°

(c) 52.2°

(b) 27.0 m, 40.4 m 2 (b) − 4

(c) 30.6°

53. (a) 16.0 m −2 2 54. (a) 3

(d) 10.2°

6

(d) 22.3 m

55. x = 65, y = 155 56. (a) 157

(b) 150

57. (a) 050°

(b) 118°

(c) 160°

(d) 298°

11 58. 16

59. (a) 26.4 cm

(b) 9.84 cm, 0.496

60. (a) 5.72 cm

(b) 6.17 cm

61. (a) 14.6 cm

(b) 23.5 cm2

(c) 45.6 cm2

62. 92.9 km 63. (a) 355 m

(b) 230.4°

Teachers’ Resource NSM 3

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64. (a) 4.77 cm

(b) 6 cm

65. (a) 20.2 cm

(b) 20

3

(c) 66.0°

(d) 59.0°

66. (a) 24.5

(b) 2

(c) 0.894

(d) 53.1°

(e) 53.1°

67. (a) 56.3°

(b) 51.8° (d) (i) 22°

(ii) 14.8 m

1

4

68. (a) 2

(b) 20.8 m

(c) 3

69. (a) 32.5°

(b) 36.6 m

(c) 37.4°

70. (a) 3

(b) 26.6°

(c) 38.9°

71. (a) 23.5 m

(b) 48 m

(c) 41.9 m

72. (a) 35.5°

(b) 23.7°

(c) 62.2 m

1

Teachers’ Resource NSM 3

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Chapter 12

Chapter 12

Secondary 3 Mathematics Mensuration – Arc Length, Sector Area, Radian Measure ANSWERS FOR ENRICHMENT ACTIVITIES

Just For Fun (pg 341) 4 colours Just For Fun (pg 343) (a), (c) Just For Fun (pg 352)

Teachers’ Resource NSM 3

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Secondary 3 Mathematics Chapter 12 Mensuration – Arc Length, Sector Area, Radian Measure GENERAL NOTES The Exploration on page 340 will lead pupils to derive the formula for the arc length and area of a sector. This activity is useful for pupils to discover the formula. Derive the relationship between radian measure and degree measure using the direct variation approach. This is also an easier way to derive the formulas for arc length and area of sectors, S = rθ and A = 12 r2θ. As the pupils had learned length of arc formula and area of sector formula, it is good to give an example to show that what they are learning now is exactly the same as what they had learnt in Secondary Two. The diagram shows a circle with centre O, radius 10 cm with AOˆ B = 600. The arc length AB is given by 600 1 3600 × 2π(10) cm = 33 π cm. 600 The area of the sector AOB = 3600 × π(102) = 1623 π cm2. π Now the angle 600 is equal to 3 radian.

∴ the arc length AB = rθ = 10 × π3 cm = 313 π cm and the area of the sector AOB = 12 r2θ π

= 12 (102) 3

= 1623 π cm2.

Teachers’ Resource NSM 3

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XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Chapter 12

Secondary 3 Mathematics Test Mensuration – Arc Length, Sector Area, Radian Measure

1. In each of the following diagrams, find (a) the perimeter of the shaded region, (b) the area of the shaded region. (i)

(ii)

[8]

2. In the diagram, PQR is a tangent to the circle centre O, radius 10.2 cm, touching the circle at Q. Given that OP = OR and angle POQ = 1.2 radians, find (a) the perimeter of the shaded region, (b) the area of the shaded region. [6]

Teachers’ Resource NSM 3

© Oxford University Press

3. The diagram shows a rectangle OLNQ of side 5 cm and 12 cm in a quarter of a circle with centre O. (a) Show that angle NOQ is 1.176 radians to three decimal places. (b) Find the radius of the circle. (c) Calculate the area of the shaded region. [3]

4. The diagram shows a circle of radius 17 m and a chord AC of length 30 m. Calculate (a) the length of arc ABC, (b) the area of the shaded region. [5]

5. Given that OQR is a sector of a circle with angle QOR = θ radians, and OR = a units, show that the area of the shaded region is given by 21 a2(θ - sin θ cos θ) Find the area of the shaded region when a = 8 and θ = 0.6. [6]

6. OLM is a sector of a circle, centre O and radius 14 m. N lies on OL such that LN = 5m. Given that angle LOM = 0.9 radian, calculate (a) the length of arc LM, (b) the length of MN, (c) the perimeter of the shaded region, (d) the area of the shaded region.

Teachers’ Resource NSM 3

[8]

© Oxford University Press

7. In the diagram, the radii OP and OQ are 8.4 cm and angle PVQ is θ radians. Given that the value of θ is 0.6, find (a) the length of arc PQ, (b) the area of the shaded region. [6]

8. In the diagram, O is the centre of the semi-circle PQRS. The quadrilateral PQRS is a trapezium with PQ // SR. Given that the diameter SR = 14 cm and PS = QR = 5 cm, calculate (a) angle POQ in radians, (b) the length of arc PS, (c) the area of the shaded segment.

[7]

9. In the diagram, AXB is an arc of a circle centre O and radius 10 cm. AYB is a semicircle with AB as diameter. If triangle AOB is equilateral, calculate (a) the length of arc AXB, (b) the area of the minor segment AXB, (c) the area of the shaded region. [7]

10. The diagram shows a circle PXQ, centre O, radius 4 cm. The radii OP and OQ are produced to R and S respectively so that PR = QS = 8 cm. An arc of a circle, centre O, radius 12 cm is drawn from R to S. If the area of the sector ORS is 54 of the area of the circle PXQ, calculate (a) angle POQ in radians, (b) the perimeter of the shaded region, (c) the area of the shaded region.

Teachers’ Resource NSM 3

[7]

© Oxford University Press

11. In the diagram, OAB is a sector of a circle centre O and radius 12 cm. The points C and D are on OA and OB respectively such that OC = OD = 7 cm. CD is a straight line. Given that the length of arc AB is 15 cm, calculate (a) angle AOB in radians, (b) the area of the shaded region. [5]

12. In the diagram, the radius of the sector OPQ is 12 cm and angle POQ = π3 . Calculate (a) the radius of the inscribed circle, (b) the area of the shaded region. [6]

13. A wheel of radius 14 cm is turning at a rate of 6 revolutions per minute. Calculate, taking π = (a) the angle through which the wheel turns in 1 second, (b) the distance moved by a point on the rim in 5 seconds.

14. The lengths of the minor and major arcs of a circle are 51 Taking π =

22 7

22

, 7 [2] [2]

1 2 cm and 80 cm respectively. 3 3

, find (a) the radius of the circle,

[2]

(b) the angle subtended at the centre by the major arc.

[2]

2

15. The arc length of a circle is 16 cm. The corresponding sector has an area of 96 cm . Find (a) the radius of the circle, (b) the angle subtended at the centre of the circle by the arc.

[3] [2]

16. The length of the minute hand of a clock is 20cm. Find the distance which the tip of the minute hand moves in 38 minutes. (Take π = 3.14 and correct your answer to 3 significant figures.) [3]

Teachers’ Resource NSM 3

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17. The minute hand of a clock is 10cm long. Find the area swept by the minute hand in 40 minutes. [3]

18. In the diagram, O is the centre of a circle with arc PQ = 16cm and ∠POQ = 35º. Find the radius of the circle correct to 3 significant figures. [4]

19. A paper fan has the shape of a sector as shown in the diagram. Find the area of the shaded, region to the nearest cm2. [3]

20. The diagram shows an arc PQ of a circle, centre O and radius 9 cm. Given that the perimeter of sector OPQ is 24.3cm and QR is a perpendicular to OQ, find the area of the shaded region. [4]

21. Find the area of a circular path 2 m wide surrounding a circular pond of radius 10 m. [3] 22. Find the areas of the shaded regions in the following diagrams. (All dimensions are in cm and all curves are circular.)

Teachers’ Resource NSM 3

[12]

© Oxford University Press

23. The diagram shows three semi-circles with radii r, 2r and 3r respectively. Find the ratio of the area of the shaded part to that of the unshaded part. [3]

24.

In the diagram, OAB is a sector of a circle ∧

of radius 8 cm. A O B = 30° and C is a point on OB such that CB = 2 cm. Find the area of the shaded region given that A is 5 cm vertically above OB. [4]

25. In the diagram, PA and PB are tangents to the circle centre O and radius 12 cm. If APˆ B = 1.38 radians, calculate the area of the shaded region. [4]

26. The diagram shows a circle of radius 13 cm and centre O. ABC is an isosceles triangle with BA = BC and AC = 10 cm. Find (a) ABˆ C in radians, (b) the area of the shaded region (give your answers correct to 3 significant figures). [6]

27. In the diagram, PSR is an arc of a circle, centre O, radius OP and POˆ R = θ radians. OP = OR = PR = 12 cm. PQR is a semi-circle with PR as diameter. (a) State the value of θ . (b) Calculate the area of (i) the sector OPSR (ii) the segment PSR (iii) the shaded region. Give your answers to 3 significant figures.

Teachers’ Resource NSM 3

[8]

© Oxford University Press

28. In the diagram, the circle centre Q touches the circle centre O internally at R. OS is the tangent to the smaller circle at T. If the radius of the smaller circle is 4 cm and OP = PR, find (a) angle ROS and angle RQT in radians, (b) the length of the minor arc RS, (c) the area of the shaded region. [7]

29. In the diagram, OLQM is a sector of a circle centre O. The segment LQM is enclosed in a rectangle LMPR. Given that LM = 36 cm and MP = 12 cm, calculate (a) the length of OL, (b) the angle LOM in radians, (c) the area of the shaded region. [6]

30. In the diagram, OAB is a sector of a circle, centre O and radius 13 cm. C lies on OB such that BC = 3.7 cm. Given that angle AOB = 1.5 rad, find (a) the length of arc AB, (b) the area of the shaded region. [5]

31. The diagram shows part of a circle, centre O, of radius 9.7 cm. The tangents at the points P and Q on the circumference of the circle meet at the point R and the angle POB is 0.84 radians. Calculate (a) the length of the perimeter of the shaded region, (b) the area of the shaded region. [7]

32. The diagram shows a pair of intersecting circles with centres at P and Q and of radii 7 cm and 5 cm. AB is the common chord and is of length 8 cm. Find (a) angle APB in radians, (b) angle AQB in radians, (c) the shaded area. [7]

Teachers’ Resource NSM 3

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33.

The area of a sector is 44 cm² and its perimeter is 30 cm. Find all the possible radii of the circle. [4]

34.

ABP and ABQ are two identical quadrants of a circle. Given that AB = 8 cm, find, correct to 4 significant figures, (a) the perimeter of the shaded region, (b) the area of the shaded region. [6]

35.

In the figure, a wire 4 metres long is bent into a sector of radius r and arc length s. (a) Express θ in terms of r. [3] (b) Find the value of r such that the area of the sector is maximum. [3] (c) Find the maximum area and the corresponding central angle. [2]

36.

PQ is a diameter of a circle with center O and radius r cm. R is a point on the circumference of the circle such that PR = QR. The arc PTQ is drawn with R as the centre. (a) Find, in terms of r, the area of triangle PQR and the area of the shaded region. What can you say about the two areas? Are they equal? [8] area of segment PTQ (b) Find the value of the ratio area of segment QSR . [4]

37.

Assume that the earth revolves around the sun in a circular orbit with uniform speed of 1.08 × 105 km/hour and that the distance between the sun and the earth is 1.46 x 108 km. The diagram shows that the earth moves from P to Q in 5 days. Find (a) the angle subtended at the centre, giving your answer in radians correct to 1 decimal place. [2] (b) the area of the shaded sector. [2]

Teachers’ Resource NSM 3

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38.

The figure shows the cross-sections of two cylindrical logs resting against each other on a level ground. Given that the radii of the crosssections are 16 cm and 9 cm, find, the perimeter and the area of the shaded region, correct to two decimal places. [6]

39.

In the diagram, O is the centre of the circle. Given that angle PSQ = 40° and the length of arc PQ = 18 cm, find (a) the radius of the circle, [3] [3] (b) the area of the sector OQRSP.

40.

The figure shows a circle with centre O and radius 5 cm. A, B and C are three points on the circumference of the circle such that triangle ABC is isosceles and BC = 8 cm. Find (a) the area of the segment BDC, [4] length of arc AB (b) the value of the ratio length of chord AB . [3]

41.

The figure shows a semicircle with centre O. ST is a diameter and the point P is on the circumference such that the chord SP = 12 cm and the chord TP = 5 cm. Calculate, correct to 3 significant figures, (a) the values, of the angles PST and POT, in radians. [4] (b) the area of the segment PQS. [3]

42.

In the figure, the radius of the sector AOB is 16 cm and angle AOB = 50o. Find, correct to 3 significant figures, (a) the radius of the inscribed circle PQR, [3] [9] (b) the area of the shaded region.

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. (a) (i) 39.2 m

(ii) 35.2 m2

2. (a) 112.8 cm

(b) 142.8 cm2

3. (b) 13 cm

(c) 69.372 cm2

4. (a) 16.7 m

(b) 766.3 m2

(b) (i) 36.2 cm

(ii) 37.3 cm2

(c) 28.6 m

(d) 38.9 m2

5. 4.3 units2 6. (a) 12.6 m

(b) 11.0 m

7. (a) 10.08 cm

(b) 9.45 cm2

8. (a) 1.68 rad

(b) 5.1 cm

(c) 16.8 cm2

9. (a) 10.5 cm

(b) 9.1 cm2

(c) 30.2 cm2

10. (a) 0.56 rad

(b) 24.9 cm

(c) 35.7 cm2

11. (a) 1.25 radians

(b) 66.7 cm2

12. (a) 4 cm

(b) 14.2 cm2

13.

(a) 36º (b) 44cm

14.

(a) 21cm (b) 220º

15.

(a) 12cm (b) 76.4º

16.

79.6cm

17.

209.4cm2

18.

26.2cm

19.

67cm2

20.

5.8cm2

Teachers’ Resource NSM 3

© Oxford University Press

21. 138.2 m2 22. (a) 1 142 cm2

(b) 209.45 cm2

(c) 114.29 cm2

(d) 32 cm2

23. 1:2 24. 1.76 cm2 25. 47.64 cm2 (b) 60.0 cm2

26. (a) 0.395 rad

(ii) 13.0 cm2

(iii) 43.5 cm2

28. (a) ROˆ S = 0.34 rad, RQˆ T = 1.91 rad

(b) 5.44 cm

(c) 5.59 cm2

29. (a) 19.5 cm

(b) 2.352 rad

(c) 119.83 cm2

30. (a) 19.5 cm

(b) 66.45 cm2

31. (a) 16.8 cm

(b) 2.5 cm2

32. (a) 1.22 rad

(b) 1.85 rad

27. (a) 1.05 rad

(b) (i) 75.4 cm2

(c) 18.0 cm2

33. 4cm or 11 cm 34. (a) 20.57 cm 35. (a)

4 −2 r

(b) 10.96 cm2 (c) 1 m2, 2 rad

(b) 1 m

36. (a) r 2 , equal area (b) 2 37. (a) 0.09 rad

(b) 9.59 × 1014 km2

38. 61.29 cm, 60.14 cm2 39. (a) 12.89 cm

(b) 406.6 cm2

40. (a) 3.125 cm2

(b) 1.238

41. (a) 0.395 rad, 1.316 rad 42. (a) 4.75 cm

(b) 18.12 cm2

(b) 17.9 cm2

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Chapter 13

Secondary 3 Mathematics Chapter 13 Geometrical Properties of Circles ANSWERS FOR ENRICHMENT ACTIVITIES Exploration (pg 382) 4 cameras (a) 6 (b) 3

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(c) 2

(d) 2

© Oxford University Press

Secondary 3 Mathematics Chapter 13 Geometrical Properties of Circles GENERAL NOTES When the diagrams given are straight forward, like those in Qn.1 of Ex 13b, most pupils have no difficulty in recognising the properties of circles such as ‘angle at centre is equal to twice the angle at circumference’ and ‘angles in the same segment are equal’. However, they will find difficulty when the diagrams given are not obvious, where construction lines need to be drawn and when knowledge of angle properties of triangles are required. Where diagrams are not drawn in the obvious manner, the teacher may ask pupils to turn the diagrams around so that they appear more apparent from another angle. Teachers may find it useful to have transparencies with angles cut out so that it can be moved about to show equal angles. The teacher may find the Geometer’s Sketchpad (GSP) a useful tool to get pupils to verify the results that (a) the angle at the centre is equal to twice the angle at the circumference subtended by the same arc, (b) the angle subtended by the diameter of a semicircle is a right angle, (c) angles in the same segment of a circle are equal, and (d) the opposite angles of a cyclic quadrilateral are supplementary. To illustrate the tangent to a circle, use a thin stick (a satay stick will be fine) as a secant, on a transparency, and move it away from the centre of the circle.

To illustrate the properties of tangents from an external point, the method of using reflection may be more easily understood by the pupils. Referring to Figure 13.18, reflect ∆OAP with OP as the line of reflection to ∆OBP. Since reflection preserves shape and size, ∆OAP and ∆OBP are congruent. ∴AP = BP, APˆO = BPˆO and AÔP = BÔP.

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XYZ SECONDARY SCHOOL Name: _________________ (

)

Class: _______

Date: ____________ Time allowed: 35 min Marks: 16

Secondary 3 Multiple-Choice Questions Chapter 13 Geometrical Properties of Circles

1. In the figure, O is the centre of the circle, TPˆR = 80° and QÔR = x°. Find x. (A) 80° (D) 120°

(B) 160° (E) 200°

(C) 100° ( )

2. In the figure, STˆP = 25°, TPˆR = 135°, SRˆP = x° and RKˆQ = y°. Calculate the value of x + y . (A) 75° (D) 70°

(B) 55° (E) 80°

(C) 85°

( ) 3. In the figure, O is the centre of the circle and PQˆR = 70°. Calculate the value of x. (A) 140° (D) 110°

(B) 210° (E) 220°

(C) 290° ( )

ˆ S = 40° and 4. In the figure, SPˆT = 100°, PQ PRˆQ = x°. Calculate the value of x. (A) 30° (D) 60°

(B) 40° (E) 80°

(C) 50°

( )

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5. In the figure, O is the centre of the figure and PR is a diameter. Which of the following is/are true? I. b + d = 180° II. d = 2 c III. a = c (A) I and II only (C) I and III only (E) all of them

(B) II and III only (D) II only ( )

6. In the figure, O is the centre of the small circle PTQ and it lies on the circumference of the big circle PKQ whose centre is A . Given that PKˆQ = 2 x °, express PTQ in terms of x . (B) 90° − x (A)180° − 2 x (D) 90° + x (C) 180° − x (E) 180° − 4 x

( )

7. In the figure, QR is the diameter of the semicircle, SPˆR = 25° and STˆR = 30°. Calculate the size of TSˆR . (A) 85° (D) 125°

(B) 90° (E) 105°

(C) 95° ( )

8. In the diagram, O is the centre of the circumscribed circle of ∆ ABC . AO is produced to meet the circle at P . Given that AÔB = 110° and BÔC = 130°, find APˆC . (A) 55° (D) 120°

(B) 60° (C) 65° (E) none of the above ( )

Teachers’ Resource NSM 3

© Oxford University Press

9. In the figure, TP and TQ are tangents to the circle. Given that PRˆQ = 65°, calculate PTˆQ . (A) 50° (D) 130°

(B) 65° (C) 115° (E) none of the above ( )

10. In the figure, O is the centre of the circle and ˆR. PÔR = 130°. Calculate PQ (A) 60° (D) 130°

(B) 65° (C) 115° (E) none of the above ( )

11. In the figure, KP and TR are tangents to the circle, KPˆQ = 65°, TRˆQ = 28° and PQˆR = x °. Find x . (A) 37° (D) 87°

(B) 90° (C) 93° (E) none of the above ( )

12. In the figure, TP and TQ are tangents to the circle, PTˆQ = 56° and PRˆQ = x °. Calculate x . (A) 112° (D) 136°

(B) 118° (C) 124° (E) cannot be found

( ) 13. In the diagram, PT is the tangent to the circle. Given that PR = QR and RPˆQ = 70°, calculate PTˆQ . (A) 30° (D) 60°

(B) 40° (E) 70°

(C) 50°

( ) Teachers’ Resource NSM 3

© Oxford University Press

14. In the diagram, TA and TB are tangents to the circle whose centre is O . If TPˆA = 30°, find the value of BÂC . (A) 20° (D) 35°

(B) 25° (E) 60°

(C) 30°

( ) 15. In the diagram, BC is the diameter and TA is a tangent to the circle. If PÂB = 62°, calculate ATˆB . (A) 28° (D) 34°

(B) 30° (E) 38°

(C) 32°

( ) 16. In the diagram, PQ , PR and QR are tangents to the circle. If PQ = PR and PQˆR = 36°, calculate APˆ C . (A) 28° (D) 64°

(B) 36° (E) 72°

(C) 48°

( )

Teachers’ Resource NSM 3

© Oxford University Press

Answers 1. B 5. B 9. A 13.A

2. C 6. B 10.C 14.C

Teachers’ Resource NSM 3

3. E 7. C 11.D 15.D

4. D 8. B 12.B 16.B

© Oxford University Press

XYZ SECONDARY SCHOOL Name: _________________ (

)

Date: ____________ Time allowed: min Marks:

Class: _______

Secondary 3 Mathematics Test Chapter 13 Geometrical Properties of Circles 1. In the diagram, O is the centre of the circle. Calculate the values of (a) x, (b) y.

[1] [1]

2. PR is the diameter of a circle, centre O. The points Q and S lie on the circumference of the circle such that PQ = RQ and QPˆ S = 65°. (a) Write down the value of PSˆR . (b) Calculate (i) QPˆ R , (ii)

PRˆ S .

[1] [1] [1]

3. In the diagram, QP = QR, PQˆ S = 34° and

PRˆ Q = 38°. Calculate (a) RPˆ S ,

[2]

(b) QSˆR .

[1]

4. In the diagram, BÂD = 92° and ABˆ C = 79°. Find (a) ATˆD ,

[2]

(b) TCˆ B .

[1]

Teachers’ Resource NSM 3

© Oxford University Press

5. In the diagram, O is the centre of the circle. Given that AÔC = 112°, calculate the following. (a) ADˆ C ,

[1]

(b) ABˆ C .

[2]

6. PQ is a diameter of the circle, centre O. Given that PQ = 15 cm and PR = 12 cm, calculate the area of triangle PQR. [3]

7. In the diagram, O is the centre of the circle. PAB and POT are straight lines. Given that

APˆ O = 14° and OBˆ A = 40°, calculate (a) ATˆB , (b) AÔP, (c) TÂB.

[4]

8. In the figure, AC is the diameter of the circle. Given that BÂC = 52° and APˆ B = 26°, calculate (a) PBˆ C , (b) BÔA.

[3]

9. In the figure, SPˆ Q = 53° and PQˆ R = 79°. Find the angles of SYˆR and QXˆR

Teachers’ Resource NSM 3

[4]

© Oxford University Press

10. In the figure, HK is parallel to BC,

HBˆ A = 32°, ABˆ C = 53° and BCˆ H = 26°. Calculate (a) HKˆ C , (b) BÂC.

[3]

11. In the diagram, O is the centre of the circle and

ABˆ E = 54°. Find the value of DCˆ E .

[3]

12. In the diagram, O is the centre of the circle, AÔB = 52° and OBˆ C = 48°. Calculate the value of OAˆ C .

[3]

13. In the diagram, AÔD is a diameter of the circle, TAOD and TBC are straight lines. Given that

ATˆC = 20° and BDˆ C = 46°, find the value of CÂD. [3]

Teachers’ Resource NSM 3

© Oxford University Press

14. In the diagram, OABCD is a quadrant of a circle, centre O. AC and BD intersect at the point X and AB = BC = CD. Find the value [3] of AXˆD .

15. In the diagram, AB is parallel to DC, chords AC and BD meet at the point T. Given that

BTˆC = 74°, find ACˆ D .

[3]

16. In the diagram, O is the centre of the circle. If AÔB = 54° and OBˆ C = 52°, find the value of OÂC. [3]

17. In the diagram, O is the centre of the circle, OÂB = a, ABˆ C = b and OCˆ B = c. Express b in terms of a and c. [4]

Teachers’ Resource NSM 3

© Oxford University Press

18. In the diagram, O is the centre of the circle of radius 6.5 cm. If AB = 5 cm and OBˆ A = θ, find the numerical values of (a) sin θ, (b) tan θ.

[3] [1]

19. In the diagram, AOB is a diameter of the circle, centre O. Given that AB || DC, DÂC = 46° and [3] ABˆ D = x°, find x.

20. In the diagram, TAB is a straight line, TA = AD and BCˆ D = 78°. Find (a) ATˆD ,

[2]

(b) ABˆ C .

[2]

21. In the diagram, O is the centre of the circle. AEOD and ABC are straight lines. If BÂO = 18° and ADˆ C = 56°, calculate (a) CÊD,

[1]

(b) ACˆ D , (c) BÔC.

[1] [2]

22. In the diagram, O is the centre of the circle. LOT and LMN are straight lines. Given that

ONˆ M = 46° and OLˆ M = 24°, calculate (a) LOˆ M ,

[1]

(b) TMˆ N ,

[2]

(c) MTˆN .

[2]

Teachers’ Resource NSM 3

© Oxford University Press

23. In the diagram, ABCD is a cyclic quadrilateral in which ADˆ C = 79°, BÂD = 82° and

ABˆ D = 62°.Find (a) BDˆ C , (b) BCˆ D , (c) BCˆ A . [5] 24. PQ and RS are two parallel chords in a circle of radius 7.5 cm. If PQ = 12 cm and RS = 9.8 cm, calculate the possible distance between the chords PQ and RS. [5]

25. In the diagram, PR is a diameter of the circle, centre O, PRˆ Q = 24° and PTˆR = 38°. Calculate (a) SRˆ P ,

[2]

(b) QSˆR ,

[2]

(c) POˆ Q .

[2]

26. In the diagram, ABˆ C = 112° and AÊD = 116°. Find the values of (a) ACˆ D ,

[2]

(b) CAˆ D .

[2]

27. In the diagram, O is the centre of the circle, TAB is a straight line, ADˆ B = 84° and TÂD = 74°. Find the value of (a) ACˆ B ,

[1]

(b) ACˆ D , (c) OAˆ D .

[2]

Teachers’ Resource NSM 3

[2]

© Oxford University Press

28. In the diagram, O is the centre of the circle, AÔB = 92° and ACˆ D = 48°. Find (a) ACˆ B ,

[1]

(b) DAˆ B , (c) DAˆ O .

[2] [2]

29. In the diagram, TAD and TBC are straight lines where A, B, C and D are points on the circle. Given that AB = AT, DÂC = 78° and ATˆB = 56°, calculate (a) BÂC, (b) ADˆ B ,

[2] [2]

(c) DBˆ C .

[1]

30. In the diagram, O is the centre of the circle, AÔC = 96° and OCˆ B = 30°. Calculate the value of OÂB. [3]

31. In the diagram, O is the centre of the circle, ADˆ B = 27° and CÔD = 96°. Calculate (a) BÂC,

[2]

(b) ABˆ C .

[2]

Teachers’ Resource NSM 3

© Oxford University Press

32. In the diagram, AB is parallel to OC, where O is the centre of the circle. Given that OBˆ C = 52°, calculate (a) BÂC,

[3]

(b) BCˆ A .

[2]

33. In the diagram, O is the centre of the circle, AC is a diameter and it meets BD at X. Given that AÔD = 86° and BÂC = 24°, calculate (a) ABˆ X ,

[1]

(b) ODˆ X , (c) BXˆC .

[2] [2]

34. In the diagram, O is the centre of the circle and

ABˆ C = 124°. Find the value of OCˆ A .

[3]

35. In the diagram, O is the centre of the circle. Given that ACˆ B = 48° and ACˆ D = 68°, find the value of (a) OBˆ A ,

[2]

(b) DAˆ O .

[2]

Teachers’ Resource NSM 3

© Oxford University Press

36. In the diagram, AOC is the diameter of the circle with centre O and TAB is a straight line. Given that BTˆC = 30° and ACˆ B = 50°, find (a) TCˆ A ,

[3]

(b) ABˆ D .

[2]

37. In the diagram, PAB, ADQ and BCQ are straight lines. Given that CDˆ Q = 52° and CQˆ D = a°, find (a) BCˆ P in terms of a,

[2]

(b) BÂD when BPˆ C = (a + 26)°

[3]

38. In the diagram, TA and TB are tangents to the circle with centre O. Given that ATˆO = 32°, find ACˆ B .

[3]

39. In the figure, BOC is a diameter of the circle and PAQ is the tangent to the circle at A. Given that APˆ C = 20° and CÂQ = 42°, calculate BCˆ P .

Teachers’ Resource NSM 3

[3]

© Oxford University Press

40. In the diagram, O is the centre of the circle, TAP is the tangent to the circle at the point A, BOCP is a straight line and APˆ C = 28°. Calculate TÂB.

[3]

41. In the diagram, TAP is the tangent to the circle at A. Given that PÂC = 66° and BÂT = 37°, [3] calculate ATˆB .

42. In the diagram, O is the centre of the circle, BC, AC and AB are tangents to the circle. Given that OÂB = 34° and OBˆ C = 24°, find the value of BCˆ A .

[3]

43. In the diagram, TA and TB are tangents to the circle at A and B respectively. Given that ATˆB = 58°, calculate APˆ B . [3]

Teachers’ Resource NSM 3

[3]

© Oxford University Press

44. In the diagram, TA and TB are tangents to the circle whose centre is at O. Given that ATˆB = 54°, calculate (a) PBˆ C ,

[1]

(b) BCˆ A , (c) BAˆ Q .

[1] [1]

45. AQB is a chord of the circle ABC. TA is the tangent to the circle at A, the tangent to the circle at B meets TQ produced at P. If ATˆP = 22° and TQˆ B = 137°, calculate TPˆ B .

[3]

46. The figure shows a circle with centre O and radius 8 cm. The diameter HK is produced to P and PAB is a tangent to the circle at A. Given that AHˆ O = 26°, calculate (a) APˆ K , (b) BAˆ H , (c) the area of the minor segment AQH. (Take π = 3.14)

[1] [1] [3]

47. In the figure, AB is a diameter of the circle and TC is a tangent to the circle at C. TC meets AB produced at T. If TÂC = 28°, calculate (a) ABˆ C , (b) ATˆC .

Teachers’ Resource NSM 3

[3]

© Oxford University Press

48. In the diagram, TA and TB are tangents to the circle whose centre is O. Given that APˆ B = 116°, find (a) AQˆ B ,

[1]

(b) ATˆB .

[3]

49. In the figure, PA and PB are tangents to the circle at A and B respectively. Given that O is the centre of the circle, OA = 2.8 cm and AP = 4.4 cm, calculate (a) PQ, (b) APˆ B .

[4]

50. In the diagram, TC and TA are tangents to the circle with centre O. Given that PÂB = 58° and ATˆC = 38°, find (a) OBˆ C , (b) OÂC.

[2] [2]

51. In the diagram, PQ, PS, RQ and RS are tangents to the circle at B, A, C and D respectively. Given that PÔA = 56° and

SRˆ O = 26° where O is the centre of the circle, calculate (a) SPˆ O ,

[2]

(b) PQˆ R .

[2]

Teachers’ Resource NSM 3

© Oxford University Press

52. In the diagram, ACT is a tangent to the circle at C. Given that COQ is a diameter, AROP is a straight line and BQˆ C = 26°, calculate (a) RPˆ C ,

[2]

(b) PAˆ T , (c) PCˆ T .

[2] [1]

53. In the diagram, O is the centre of the circle and TA is the tangent to the circle at A. The diameter BD and AC meet at X. Given that BDˆ C = 26° and DÂO = 36°, calculate (a) BAˆ T ,

[2]

(b) OBˆ A , (c) ABˆ C , (d) BXˆC .

[1] [1] [2]

54. In the diagram, AB, BC and AC are tangents to the circle at P, Q and R respectively. If

ABˆ C = 44° and QPˆ R = 48°, calculate (a) BAˆ C ,

[3]

(b) PQˆ R .

[2]

55. In the diagram, TAP and TBQ are tangents to the circle at A and B respectively. Given that TAP is parallel to BC and ATˆB = 50°, calculate (a) PÂC, (b) BÂC.

Teachers’ Resource NSM 3

[3] [2]

© Oxford University Press

56. In the figure, PAQ and QBR are tangents to the the circle at A and B respectively. Given that PÂC = 70° and RBˆ C = 52°, calculate (a) AQˆ B ,

[2]

(b) ACˆ B .

[2]

57. In the diagram, AB and AC are tangents to the circle at B and C respectively. Given that

BAˆ C = x°, express BPˆ C in terms of x.

[4]

58. In the diagram, O is the centre of the circle and HK is a tangent to the circle at A. Given that ADˆ B = 10y°, ABˆ D = 2x°, CDˆ B = x° and

DBˆ C = 14y°, calculate, in degrees, (a) COˆ B ,

[3]

(b) ACˆ D , (c) KAˆ B .

[1] [1]

59. In the diagram, PAT is a tangent to the circle at A, AC is a diameter, BED is a straight line and BE = BC. Given that CBˆ E = 2x°, find in terms of x (a) AÔD, (b) BÂT, (c) PÂD.

Teachers’ Resource NSM 3

[2] [2] [2]

© Oxford University Press

60. In the figure, PQR is a triangle inscribed in the circle. AB, BC and AC are tangents to the circle. Given that QPˆ R = 63° and PRˆ Q = 48°, calculate (a) ABˆ C ,

[2]

(b) BAˆ C ,

[2]

(c) ACˆ B .

[1]

61. PA and PB are tangents to a circle, centre O, touching the circle at A and B. BOC is a diameter and CÂO = 48°. Calculate (a) AOˆ C , (b) ABˆ O , (c) APˆ B .

[6]

62. In the figure, PAB is the tangent to the circle at A and PQS is a straight line. Given that AQ = QR, BÂS = 62° and APˆ Q = 32°, calculate (a) QAˆ P , (b) QRˆ S (c) RSˆA .

[5]

63. In the diagram, TA is a tangent to the circle. AB is parallel to the diameter DOC. CODT is a straight line and ADˆ C = 62°. (a) Give a brief reason why TÂO = 90°.

[1]

(b) Name a pair of congruent triangles and give a brief reason to substantiate your claim. [2] (c) Calculate the value of (i) TAˆ D , (ii) (iii)

CTˆA , BOˆ C .

Teachers’ Resource NSM 3

[1] [1] [1] © Oxford University Press

64. CT is a tangent to a circle, centre O and radius 6 cm. DOC and DAT are straight lines and AÔC = 70°. Calculate (a) the area of the sector OABC, taking π to 22

be 7 , (b) the area of ∆OAC, (c) the area of the minor segment ABC,

[2]

(d) CDˆ A , (e) the length of the tangent CT.

[2] [2]

[2] [2]

65. In the diagram, O is the centre of the circle, AD is the diameter, OBˆA = 48° and BC = CD. Calculate the following: (a) OÂB (c) BCˆD

(b) ABˆC ˆC (d) AD

[8]

66. In the figure, O is the centre of the circle. The chords AC and BD are perpendicular, OÂD = x° and BÂC = y°. (a) Express AÔD in terms of x. (b) Express ACˆD in terms of y. (c) Show that x = y.

[6]

67. In the diagram, O is the centre of the circle and PQRS is a parallelogram. Given that PQˆR = 52°, calculate the following: (a) PTR

(b) SÔT

Teachers’ Resource NSM 3

[4]

© Oxford University Press

68. The diagram shows a pentagon ABCDE inscribed in a circle with centre O. Given that AB = BC = CD and ABˆC = 130°, calculate the following: (a) AÊB

(b) AÊD

(c) CÔD [6]

69. In the diagram, O is the centre of the circle, AOC is a diameter and CD is parallel to BE. Given that AÔB = 88° and ACˆE = 24°, calculate the following: (a) BÊC

(b) BCˆD

(c) CÊD [6]

70. An equilateral triangle of side 12 cm is drawn in a circle with its edges touching the circumference. Calculate the radius of the circle. [4] 71. An isosceles triangle of sides 6 cm, 6 cm and 8 cm long is inscribed in a circle. Find the radius of the circle. [4] 72. In a circle of diameter 12 cm, PQ and HK are two parallel chords of lengths 8 cm and 5 cm respectively. Calculate the distance between the chords if they are on (a) the same side of the centre, (b) opposite sides of the centre. [4] 73. In the figure, O is the centre of the circle. If BÂO = 35° and BCˆO = 29°, calculate AÔC as indicated in the diagram. [3]

Teachers’ Resource NSM 3

© Oxford University Press

74. In the figure, AC is the diameter of the circle whose centre is O. If AD = BD and CBˆD = 18°, calculate the following angles:

ˆB (a) AD

(b) BCˆD

(c) CÂD [6]

75. In the figure, O is the centre of the circle. AÔE = 68° and OBˆD = 44°. Calculate the following angles: (a) BÊD

(b) OCˆ B

(c) OTˆE [6]

76. In the diagram, PT, QT are tangents to the circle and PTˆQ = 60°. If the radius of the circle is 14 cm, find the length of the minor 22 [3] arc PQ. (Take π = 7 )

77. In the diagram, PA and PB are tangents to a circle with centre O. If ACˆB = 58°, AO = 10 cm, find the following. (a) AÔB (c) APˆB

(b) OÂB (d) the length of AP [8]

78. In the diagram, TAP is a tangent to the circle ˆ C = 44° at A, TAP is parallel to QCD, AQ and PÂD = 62°. Calculate (a) BCˆD ,

ˆ B, (b) AD

Teachers’ Resource NSM 3

ˆC. (c) BD [6]

© Oxford University Press

79. In the diagram, TAP is a tangent to the circle at A. Given that AXˆE = 57° and TÂE = 34°, if AD is a diameter, find (a) AÊX, (b) ABˆC , (c) DÊX.

[6]

80. In the diagram, TC and TAP are tangents to the circle with centre O. Given that CÂO = 21°, calculate (a) APˆB ,

(b) ATˆC ,

(c) PÂB. [6]

81. In the figure, O is the centre of the circle. TAP and TBQ are tangents to the circle at A and B respectively. Given that ATˆB = 54° and BCˆD = 116°, calculate (a) PÂD,

(b) ABˆO .

[4]

82. In the diagram, PA and PB are tangents to the circle at A and B. The chords AC and BD meet at X. Given that DÂT = 35°, PÂB = 57° and CBˆQ = 62°, calculate the following: (a) APˆB

(b) ABˆC

Teachers’ Resource NSM 3

(c) BXˆC [6]

© Oxford University Press

83. In the diagram, AQ and CP are tangents to the circle at A and C respectively. Given that BÂQ = 48° and ABˆC = 67°, calculate [3] BCˆP .

84. In the diagram, AQ and DP are tangents to the circle at A and D respectively. Given that ˆ C = 30°, QÂB = 60° and BÂC = 36°, PD calculate the following: (a) ABˆC

(b) ACˆ D

Teachers’ Resource NSM 3

[5]

© Oxford University Press

Answers 1. (a) 55

(b) 125

2. (a) 90°

(b) (i) 45°

3. (a) 70°

(b) 38°

4. (a) 13°

(b) 88°

5. (a) 56°

(b) 124°

(ii) 70°

6. 54 cm2

7. (a) 50°

(b) 26°

8. (a) 12°

(b) 76°

(c) 27°

9. 48° ; 26° 10. (a) 122°

(b) 69°

11. 36° 12. 54° 13. 32° 14. 150°

15. 37°

16. 25° 17. b = a + c 12

18. (a) 13

12

(b) 5

19. 22° 20. (a) 51°

(b) 51°

21. (a) 34°

(b) 106°

(c) 80°

22. (a) 22°

(b) 35°

(c) 44°

Teachers’ Resource NSM 3

© Oxford University Press

23. (a) 43°

(b) 98°

(c) 36°

25. (a) 28°

(b) 66°

(c) 48°

26. (a) 64°

(b) 48°

27. (a) 42°

(b) 32°

(c) 58°

28. (a) 46°

(b) 86°

(c) 42°

29. (a) 34°

(b) 22°

(c) 78°

24. 1.18 cm or 10.18 cm

30. 18° 31. (a) 42°

(b) 111°

32. (a) 38°

(b) 14°

33. (a) 43°

(b) 19°

(c) 67°

34. 34°

35. (a) 42°

(b) 22°

36. (a) 10°

(b) 10°

37. (a) (52 + a)°

(b) 103°

38. 58°

39. 26° 40. 59° 41. 29° 42. 64° 43. 119° 44. (a) 27°

(b) 63°

(c) 117°

45. 72°

Teachers’ Resource NSM 3

© Oxford University Press

46. (a) 38°

(b) 64°

47. (a) 62°

(b) 34°

48. (a) 64°

(b) 52°

49. (a) 2.42 cm

(b) 64.9°

50. (a) 39°

(b) 19°

51. (a) 34°

(b) 120°

52. (a) 26°

(b) 38°

(c) 64°

53. (a) 144°

(b) 54°

(c) 118°

54. (a) 52°

(b) 64°

55. (a) 65°

(b) 50°

56. (a) 64°

(b) 58°

(c) 46.2 cm2

(d) 80°

x

57. (90 + 2 )° 58. (a) 40°

(b) 40°

(c) 50°

59. (a) 180° − 4x°

(b) 90° − x°

(c) 90° − 2x°

60. (a) 84°

(b) 42°

(c) 54°

61. (a) 84°

(b) 42°

(c) 84°

62. (a) 30°

(b) 92°

(c) 60°

63. (a) radius is perpendicular to tangent (c) (i) 28° (ii) 34° (iii) 56° 64. (a) 22 cm2 (d) 35°

(b) 16.9 cm2 (e) 8.4 cm2

65. (a) 48°

(b) 114°

66. (a) 180° − 2x 67. (a) 52°

(b) ∆OAD, ∆OBC ; SAS

(c) 5.1 cm2 0.7

(c) 132°

(d) 66°

(b) 90° − y (b) 104°

Teachers’ Resource NSM 3

© Oxford University Press

68. (a) 25°

(b) 75°

(c) 50°

69. (a) 46°

(b) 114°

(c) 20°

70. 6.93 cm 71. 4.02 cm 72. (a) 0.98 cm

(b) 9.93 cm

73. 128 ° 74. (a) 36°

(b) 108°

(c) 18°

75. (a) 46°

(b) 62°

(c) 22°

77. (a) 116°

(b) 32°

(c) 64°

78. (a) 106°

(b) 44°

(c) 18°

79. (a) 67°

(b) 113°

(c) 23°

80. (a) 48°

(b) 42°

(c) 21°

81. (a) 53°

(b) 27°

82. (a) 55°

(b) 63°

1 76. 29 3 cm (d) 16 cm

(c) 95°

83. 113° 84. (a) 84°

(b) 54°

Teachers’ Resource NSM 3

© Oxford University Press